The Spot SDK documentation is best viewed via our developer site at dev.bostondynamics.com.
- Prompt severity can now be read from the blackboard using the
severity_in_blackboard
field (if specified) in the Prompt message.
- The robot can now be commanded to traverse large areas with no stereo data by setting the
disable_missing_data_cliffs
field in the MobilityParams message totrue
. Users must exercise extreme caution when setting this field totrue
.
- The
_get_streamed_download_graph
method is now defined, thereby fixing the issue with therecording_command_line.py
example in 4.1.0.
- One known issue in CORE I/O version 4.1.0 is that Extensions with names that violate the naming requirements cannot be uninstalled through the web portal. Please see here for more information.
- Same as 4.1.0
-
The
BeginCallbackRequest
message will no longer have therecorded_data
field filled out. Area callback services should continue to use the existingcustom_params
inBeginCallbackRequest
instead of trying to read the duplicate data from insiderecorded_data
. -
The asynchronous call,
get_choreography_status_async
in Choreography Client will no longer return a Future and a validity time as a tuple directly. Nowget_choreography_status_async
will only return a Future, and callingresult()
on that Future will return a tuple with the GetChoreographyStatus response and the validity time instead of only returning the status response. No changes were made to the non-asynchronous version of the call,get_choreography_status
. -
The
flat_ground
field in the Annotations message in the Edge message may no longer be functional. Please useground_clutter_mode
instead.
-
Support for predetermined, human-robot interaction (HRI) behaviors has been added to autowalk. A new field,
hri_behaviors
, has been added to the GlobalParameters message. Settingplay_alert_behaviors
totrue
will result in Spot tapping its front-left foot twice if anomalies are discovered during an inspection. Settingplay_undock_behaviors
totrue
will result in Spot raising and lowering its legs twice before undocking. -
Support for multiple docks has been added to autowalk. Two new fields,
disable_recharge
anddisable_end
have been added to the Dock message. Settingdisable_recharge
totrue
determines whether the robot can use the corresponding dock for recharging or executing a return to dock and try again later failure behavior. Settingdisable_end
totrue
determines whether the robot can end the mission on the corresponding dock. -
Support for mission text has been added to missions via the CreateMissionText node type. Mission text is similar to prompts (e.g., the action failed, what would you like to do?), minus the answering functionality. It can be used to communicate the mission status to users, among other things. Clients can retrieve all active mission text through the GetState RPC, where active means the mission text node has been ticked and is running. Please see the
active_mission_text
field in the State message for more information. -
Support for querying Data Acquisition Store has been added to missions via the BosdynQueryStoredCaptures node type. This node type queries Data Acquisition Store and writes the corresponding
QueryStoredCapturesResponse
to the blackboard. If a client needs inspection-dependent behavior (e.g., inspection B is contingent on the outcome of inspection A), this node can be used to help accomplish that (assuming inspection A writes data to the Data Acquisition Store). The aforementioned HRI behaviors rely on this new node type, among other things, under the hood. After an inspection, the Data Acquisition Store is queried to determine if an anomaly was found during that inspection, then the robot behaves accordingly.
- Async streaming is now supported in the Python SDK. The StoreDataStream and QueryStoredCaptures RPCs are two examples of streaming RPCs that can now be called in an async manner. Please see the corresponding client implementation in the
store_file_async
,store_data_as_chunks_async
, andquery_stored_captures_async
methods in the DataAcquisitionClient for examples of usage.
Please see common.py. Tests for async streaming have been added to test_base_client.py
.
- Files in excess of 100 MB can now be stored in a single RPC using the StoreDataStream RPC. This functionality is useful for payloads that produce files in excess of 100 MB (e.g., laser scanners). Please note that the Data Acquisition Store capacity is 50 GB and writing files before existing data is offloaded will result in existing data being overwritten. The new field,
include_large
, in the QueryParameters message controls whether captures in excess of 100 MB are included in the QueryStoredCapturesResponse message.DataAcquisitionStoreHelper
andDataAcquisitionStoreClient
have been updated accordingly. Please see data_acquisition_plugin_service.py and data_acquisition_store.py, respectively.
-
Support for uploading and downloading graphs larger than 4 MB has been added via the UploadGraphStreaming and DownloadGraphStreaming RPCs, respectively.
-
Area Callback implementations are now informed of whether the robot is already inside the callback region at the beginning of the callback, rather than starting from the edge of the region as usual. This can be used by the callback to provide better behavior for restarting or re-routing. This can happen in some cases when the robot gets stuck inside the region, and restarts navigation with a new navigation command.
- The Keepalive Service is no longer in beta and is now in use by Spot, the tablet, and Orbit. This service unifies and expands the comms-loss behaviors of Spot. It lets a client specify one or more Policies, each containing one or more actions. Each action will automatically occur if a client does not send a CheckInRequest within a configurable amount of time. Please see here for more information.
-
The robot can now detect and classify objects or regions in the world as obstacles or areas to avoid that previously would not have been classified as such. The
hazard_detection_mode
field in the MobilityParams message controls whether the feature is on, and if it is on, the strictness of navigation around the detected hazards. -
The robot can now be restricted from ascending or descending stairs by using the new
STAIRS_MODE_PROHIBITED
enumerator in theStairsMode
enum type in the MobilityParams message. -
No-go regions now support circles via the new field,
circle
, in the NoGoRegionProperties message. -
A new planner_mode field has been added to the TravelParams message. If this is set to PLANNER_MODE_DEFAULT or PLANNER_MODE_SHORT_RANGE, the default navigation path planner will be used. If this is set to PLANNER_MODE_LONG_RANGE, the new experimental Long Range Planner will be used. The Long Range Planner allows the robot to navigate around large obstacles that were not present during mission recording. When the Long Range Planner is enabled, the robot will be allowed to deviate up to 6 m from the recorded path, as compared to 1.5 m when using the default path planner, and 0.25 m when strict path following is enabled. Caution is recommended when using the Long Range Planner, since the robot may walk into a hazardous or undesired area.
-
Support for choreography moves that are relative to the move start or dance frame has been added to Choreographer via three new fields,
relative_position
,relative_yaw
, andrelative
in the GotoParams message. Therelative_position
andrelative_yaw
fields control the robot's position and orientation (yaw), respectively. Therelative
field controls whether the motion is relative to the move start (true
) or dance frame (false
). Please see Move Reference for more information. -
Support for three new move types that control the robot's status lights, AV lights, and AV buzzer has been added to Choreographer via the SetAudioVisualColorParams, BuzzerNoteParams, and SetAllColorParams messages, respectively. In MoveParams, the
set_audio_visual_color_params
,buzzer_note_params
, andset_all_color_params
fields control the robot's AV lights, AV buzzer, and status lights, respectively. Please see the Move Reference for more information. -
Additional options have been added for generating
custom_gait
motion from valid Animations with thecustom_gait_cycle
option. See the Animation files for Choreographer documentation for additional details on Animation file options and the Custom Gait documentation for additional details on thecustom_gait
move. These new options,enable_body_offset
,enable_body_motion
, andenable_swings_xy
, add support for using animation input for the body motion of acustom_gait
move and the x-y motion of thecustom_gait
swing trajectories. See the AnimatedCycleParams message for additional information on theanimated_cycle_params
options. -
The
animate_move_params_file
argument is now required in theconvert_animation_file_to_proto
function if default move parameter values are needed. Please see animation_file_to_proto.py.
-
The
ResponseContext
class has been updated such that if the response header does not contain a response timestamp, it sets the response timestamp. -
A bug in the
oneof_param_to_dict
function in the service customization helpers has been fixed. The function now returnsDict
instead ofList
. -
Support for the
Keepalive Service
has been added to the command-line client. Please see command_line.py.
-
Support for a new field,
extension_name
, has been added for Extensions (via the requiredmanifest.json
file). This field represents the name of the extension. If noextension_name
is provided, the extension name defaults to the name of the spx file as before. Please see here for more information. -
Support for the
journald
logging driver has been added for Extensions (via the requireddocker-compose.yml
file). Usage of thejournald
logging driver enables developers to retrieve logs for containers that are no longer running, even after a power cycle. Please see the CORE I/O documentation for more information. If no logging driver is specified in thedocker-compose.yml
file, the Extension uses thejournald
logging driver.
-
A new reference frame, "feet_center", has been added. This frame is gravity-aligned and represents the robot's footprint. The origin is at the geometric center of the robot's feet. The x-axis is aligned such that it points from the center of the rear feet to the center of the front feet in the x-y plane.
-
Support for the
seed
andwaypoint
frames has been added to frame_helpers.py. Theseed
frame is a global reference frame for a Graph Nav map. Its metric consistency may be improved using the ProcessAnchoring RPC. For example, suppose a Graph Nav map were recorded on a construction site where "survey targets" the robot could recognize (e.g., AprilTags) had been measured with millimeter-level accuracy using a Total Measurement Station. The robot's pose in thisseed
frame is advantageous from a registration perspective for laser scans collected using a laser scanner that may not necessarily be capable of tracking its localization accurately in challenging environments because it can inform the laser scanner of where it actually is with high accuracy. Similarly, the robot's pose relative to thewaypoint
frame may also be important if the robot is expected to perform some action there that requires a high degree of repeatability. The added support for these frames in the frame helpers allows developers to focus on the high-level, value-added tasks.
-
Clients are now informed by Graph Nav if they send a SetLocalizationRequest message to the robot and no map is loaded. The new status,
STATUS_NO_MAP_LOADED
, is returned in thestatus
field in the response (SetLocalizationResponse message type). This status indicates that localization failed because no map is currently loaded. -
More granular control over whether the robot has reached its goal is now available via the
box_region
field in the TravelParams message. Clients can now specify a oriented 2D rectangle relative to a waypoint using the OrientedBox2 message. Previously, only amax_distance
(2D circle with radiusmax_distance
) andmax_yaw
were supported. Similarly, while navigating an edge at playback, the max distance from the recorded edge that the robot is allowed to travel when avoiding obstacles or optimizing its path is configurable using themax_corridor_distance
field in the edge Annotations message. -
The lost detector, which is responsible for determining when the robot is lost, is now configurable. If the robot is regularly getting lost on site in a particular location, where, for example, its surroundings change regularly, this may be of use. The strictness of the lost detector can be configured using the LostDetectorStrictness enum type. Similarly, if there are particular, problematic regions at a given waypoint, the RegionWithFrame message may be used to configure how scan matching or other parameters work. For example, there could be a particular region at a waypoint where the scene changed frequently, thereby causing the robot to get lost. Assuming no risks from a navigation or safety perspective are in the vicinity (e.g., an unprotected fall), the
lost_detector_strictness
field could be set toLOST_DETECTOR_STRICTNESS_PERMISSIVE
. The dynamic region could be indicated using theregions
field, setting thedata_filter
field in the Region message toDATA_FILTER_IGNORE
. These settings are per Waypoint. To debug the lost detector, use thelost_detector_state
field in the GetLocalizationStateResponse message. -
More granular control of the feature matching behavior of topology processing is now available via the FeatureMatchingParams message. A new field,
feature_matching_params
, has been added to the Params message that controls whether and how sparse feature matching is performed during topology processing. At present, the how is limited to simply enabling/disabling feature matching. Please see here for more information. -
The Python SDK now raises
LicenseError
if the robot's license is not valid when callingupload_graph()
,start_recording()
, orcreate_waypoint()
. Previously they incorrectly raisedUnsetStatusError
.
- Additional mission node data can now be read from the blackboard at playback. The updated node types and data that can be read are:
Node Type | Data |
---|---|
ForDuration | Duration (google.protobuf.Duration ) |
BosdynNavigateRoute | graph_nav_pb2.NavigateRouteRequest |
BosdynGraphNavLocalize | graph_nav_pb2.SetLocalizationRequest |
Prompt | List of options (nodes_pb2.OptionsList ) |
Dock | Docking station ID (uint32 ) |
- The default IP address for all Rajant ES1 Radios shipped from Boston Dynamics is 192.168.50.9.
- The behavior state of the robot can now be determined in a simpler fashion via the new
behavior_state
field in the RobotState message. Behavior states currently include standing, stepping, transitioning from sitting to standing and vice versa, unready to move, and unknown. Clients that were previously relying on their own heuristics to determine this type of information may benefit from this new field.
-
In the
AreaCallbackData
message, thecustom_params
field is being replaced by theparam_collection
field, which contains the same values, but also the specification used to edit them. For the time being, thecustom_params
field will still be filled out during recording, but any usage of that field should be migrated to prefer theparam_collection
values. -
In the
PlaybackMode
message, theskip_docking_after_completion
field is being replaced by thedisable_end
field in theDock
message. Settingskip_docking_after_completion
totrue
is the same as settingdisable_end
totrue
for everyDock
. -
Currently the mission service supports blackboard variable keys that contain ".", "[]", and "()". In a future release, this will no longer be supported. Boston Dynamics recommends using letters, numbers, and underscores for blackboard keys.
- The TimeSync client may lose time sync with the robot, and eventually the client time may drift far enough away from the robot time that the robot starts rejecting the client's messages.
- Same as 4.0.2
-
Area Callback Crosswalk and Area Callback Look Both Ways: The
area_callback_crosswalk.py
andarea_callback_look_both_ways.py
examples now utilize the newstarting_inside_region
field mentioned above in the 4.1.0 release notes. Custom parameters have also been added to the latter example to allow the user to configure the yaw. -
Build Extension: The
build_extension.py
example now checks if docker-compose.yml and manifest.json are malformed. Please note that it does not check whether all required fields are there. -
Get Depth Plus Visual Image: The
get_depth_plus_visual_image.py
example now supports querying the gripper camera. -
GPS: The
gps_listener.py
now self-registers the GPS device as a payload on Spot. Please note that the corresponding docker-compose.yml file needs to be updated. Additionally, some of the command-line parameters in the docker-compose.yml files have been updated. "Support" for two additional receivers has been added, namely theByNav C2-M2X
andu-blox ZED-F9R
. "Support" is written in quotations because strictly speaking, these payloads are neither officially supported nor endorsed by Boston Dynamics. Finally, a workaround for an issue with the TimeSync client where the robot would start rejecting the GPS data has been implemented. When this workaround is enabled (by adding"--disable-time-sync"
to thedocker-compose.yml
file), the client uses the CORE I/O system time, which is synchronized with the robot time using NTP, thereby negating the need to use the time sync client. Please note that the underlying issue with the time sync client has not yet been resolved and that this issue may apply more generally. -
Remote Mission Service Examples: A bug, whereby the user would be unable to select who the robot should say "hello" to on the tablet, has been fixed in the
hello_world_mission_service.py
example. Theremote_mission_client.py
example has been made more autowalk-friendly. Previously, the example and autowalk would fight for control over the robot due to the example powering off the robot. Now, the robot simply performs "the wave" instead. -
Replay Mission: A bug that caused the
replay_mission.py
example to crash has been fixed. -
Save File Plugin Service and Data Acquisition Plugin - Custom Params: These examples now use methods that use the new StoreDataStream RPC under the hood. Please note that these examples will no longer work if the robot software version is before 4.1.0.
-
Data Acquisition Download: This example now additionally supports the QueryStoredCaptures RPC.
-
Simple Alert Server: The breaking change reported in 4.0.1, but present since 4.0.0 has been fixed for the
simple_alert_server.py
example. Thestatus
in theWorkerComputeResponse
is set toNETWORK_COMPUTE_STATUS_SUCCESS
. -
Velodyne Client: A deprecation warning associated with NumPy >= 2.0.0 has been fixed.
-
View GraphNav Map in a Web Browser: The
view_gps.py
example now supports filtering the GPS data by relative time. This can be useful for reducing the rendering workload if the GPS's update rate is really high. -
Arm Gcode Example: The
arm_gcode.py
example now supports a tool length value configurable by the user to account for the length of chalk held by the gripper. This is found ingcode.cfg
. Drawing sequences now pause at the start to allow the user to insert chalk into the open gripper and close the gripper on command. Other updates include consistent use of the vision frame for localization, ground plane estimation, and drawing location. Draw on wall stability is improved but this feature remains in beta.
-
Orbit API Documentation: Though not an example, the Orbit API documentation is significantly improved. High-level concepts are still described on the About Orbit page.
-
Orbit Client: The Orbit Client now supports
PATCH
endpoints on Orbit via thepatch_resource
method. In addition, five new methods:patch_anomaly_by_id
,patch_bulk_close_anomalies
,get_site_walk_archive_by_id
,post_backup_task
, anddelete_backup
have been added. For examples demonstrating usage of these new methods, please see the Get Anomalies example for the first two methods, the Export SiteWalk Archive(s) for the third method, and the Get Backup example for the last two methods. Please note that the deprecated Scout Client has not been updated. -
Get Backup: The
get_backup.py
example shows how to retrieve a backup from Orbit. -
Get Anomalies: The
get_anomalies.py
andpatch_anomalies.py
examples show how to retrieve and edit anomaly data using the Orbit Client, respectively. Anomalies are more commonly known as alerts. -
Export SiteWalk Archive(s): The
export_site_walk_archives.py
example shows how to retrieve SiteWalk(s) using the Orbit Client. A SiteWalk describes a series of tasks that define autonomous robot operation. It contains SiteElements and SiteDocks, among other things. A SiteWalk archive is simply a compressed file containing a Graph Nav map and a .walk file. The .walk file is a serialized protobuf message of type Walk. -
Webhook Integration: The
webhook_integration.py
example is a separate example that builds on the existing Webhook Example, by additionally listening for webhooks, then performing some data maniuplation on said webhooks before sending the result to an external Enterprise Asset Management (EAM) system. The example may be run on Orbit by building an Orbit Extension and deploying it to Orbit.
-
Send Robot Back to Dock: The
send_robot_back_to_dock.py
example now supports skipping initialization, which can be useful if the robot is already localized to the map. -
Orbit Client: An issue with the
post_export_as_walk
method has been fixed. TheSiteWalk UUID
is now included in the JSON arguments, not appended to the POST request URL as it was before. Thepost_dispatch_mission_to_robot
method now supports theskip_initialization
argument, which controls whether the robot should skip initialization when starting the return to dock mission. The deprecated Scout Client has also been updated.
- No changes from 4.0.2
- No changes from 4.0.2
- No changes from 4.0.2
- Same as 4.0.1
The Joint Control API allows for low-level control of the robot's joints. Note that this API is experimental and license-limited; the robot must have a Joint Level Control license installed in order for this API to be used. Please see the documentation for more information and supplemental robot information which may be useful for development or simulation of the robot.
- A new field,
return_animation_names_only
, has been added to the GetChoreographySequenceRequest message. This field allows clients to save bandwidth by requesting only the animation names and not the entire animation for the specified choreography sequence. Correspondingly, a new message,GetAnimation
, allows clients to request individual animations by name.
- Two new fields,
kinematic_state
andcontact_states
, have been added to the RobotStateStreamResponse message. Thekinematic_state
field contains information about the pose and velocity of the robot body frame in the odom and vision frames. Thecontact_states
field contains information about the foot positions and contact state, on a per-foot basis, of the robot. TheGetRobotStateStream
RPC is a lightweight, streaming version of theGetRobotState
RPC that clients who need the lowest latency possible can use (e.g., users of the Joint Control API).
- The Orbit Client now works on Python 3.6 and Python 3.7. Previously, it was broken on those Python versions due to an import failure. The deprecated Scout Client had the same issue and has also been fixed.
- Same as 4.0.1
- Same as 4.0.1
- Joint Control: Robot Squat: An example that utilizes the joint control API to move the robot for a robot without an arm attached.
- Joint Control: Wiggle Arm: An example that utilizes the joint control API to move the robot for a robot with an arm attached.
- GPS Listener: A bug that caused this example to crash when a GPS receiver published an NMEA message without a timestamp has been fixed. The NMEAParser now ignores NMEA messages without timestamps. In addition to that, the baud rate of the GPS receiver used in conjunction with this example is now configurable via a command-line argument.
- Hello Webhook: A bug that caused this example to crash when the webhook event type was
TEST
has been fixed. TheTEST
event type is useful for debugging webhooks without having to perform an action using the robot.
- A breaking change that was present in 4.0.0, but was unfortunately not reported, is that Network Compute Bridge workers are now required to set the status field. Previously, this was not required. One of the Network Compute Bridge examples has been updated accordingly (see here).
-
In Spot software versions prior to 4.0.1, the
bosdyn.client.power.power_off_robot
andbosdyn.client.power.safe_power_off_robot
methods may not de-energize the robot. Note that thesafe_power_off_robot
method will still cause the robot’s motors to power off, but will not cause the entire robot to shut down. If your robot uses this or any integration that relies on the programmatic full shutdown, and your robot is affected by this issue, we recommend updating to 4.0.1 or later Spot software. -
Orbit Client and Scout Client: For developers on Python <= 3.8, the Orbit and (deprecated) Scout clients failed to import due to the use of a feature that is only available starting in Python 3.9. This feature is no longer used.
-
Examples that use the
GrpcServiceRunner
inbosdyn.client.server_util
with the default argumentforce_sigint_capture=True
no longer fail on Windows. A check for the Operating System (OS) has been added so that this does not happen. -
The diagnostics and exception handling in
bosdyn.client.area_callback_service_utils
have been improved. -
Fixed an issue where the robot would try to walk up the center of very wide staircases. Now, it stays closer to the recorded path up the staircase. The path on the stairs can be overridden by changing a new field,
traversal_y_offset
, which has been added to the edge annotations message.
In addition to those listed for 4.0.0:
- GraphNav map edge annotations:
flat_ground
- Same as 4.0.0
-
Tester Programs: The instructions for the tester programs that may be used to test image services and data acquisition plugins have been made more clear.
-
Fan Control: Fixed flipped
response
andrequest
arguments, which caused theGetRemoteMissionServiceInfo
method to fail. -
Network Request: Fixed flipped
response
andrequest
arguments, which caused theGetRemoteMissionServiceInfo
method to fail. -
Power Off Mission Service Callback: Fixed flipped
response
andrequest
arguments, which caused theGetRemoteMissionServiceInfo
method to fail. -
Build Extension: The
build_extension.py
script now defaults to building Extensions for the ARM64 architecture now. -
Comms Test: The command to run the Docker image has been updated (previously, it was incorrect).
-
Edit Autowalk: The mission status is now printed regularly, as well as any mission questions as they occur.
-
Custom Parameter Image Server: This example now works on CORE I/O. A webcam that is compatible with CORE I/O is required (e.g., Logitech, Inc. HD Pro Webcam C920).
-
Post-Docking Callback: Fixed an issue where the example would break if a time period was supplied.
-
Spot Light: A brightness threshold has been added, so that if the user does not have a light that is bright enough, they can adjust the threshold so that the robot will stand.
-
Network Compute Bridge Worker (Fire Extinguisher): The instructions have been updated to demonstrate how to configure the Inspection in the tablet.
-
Network Compute Bridge Worker (TensorFlow): The
status
field in NetworkComputeResponse is now set.
-
Orbit API: The name of the
site_elements
endpoint has been corrected (previouslySiteElements
). -
Orbit Send Robot Back to Dock: The example has been made more interactive.
The following fields and services have been removed.
LogAnnotationService
- Auth application token,
application_token
, and its corresponding statuses,STATUS_INVALID_APPLICATION_TOKEN
andSTATUS_EXPIRED_APPLICATION_TOKEN
- Robot commands: non-synchronized mobility commands. Top-level feedback messages.
- Graph Nav map edge annotations:
vel_limit
,ground_mu_hint
,grated_floor
- SpotCheck feedback:
foot_height_results
andleg_pair_results
The mapping between voltage and GPIO pins on the CoreIO has changed as part of the Jetpack 5 update. {5: 133, 12: 19, 24: 148} is now {5: 440, 12: 320, 24: 453}. Please see the updated CoreIO GPIO example.
Network Compute Bridge workers are now required to set the status field. Previously, this was not required.
-
The focus state of the SpotCam PTZ is now configurable using
focus_state
. The tablet allows the user to configure the SpotCam PTZ focus during autowalk recording. Clients that previously were unable to use theSpotCamAlignment
action wrapper because of issues with auto-focus may now use this action wrapper with the desired manual focus setting. -
The stow behavior of Spot's arm while Spot is navigating to its next
Target
is now configurable usingtarget_stow_behavior
. -
The gripper behavior of Spot's arm after Spot has executed an action is now configurable using
disable_post_action_close
. -
Support for Choreography has been added to autowalk. Please see the
MissionUploadChoreography
andExecuteChoreography
messages. The robot must have a choreography license in order to use this. Please see the choreography documentation for more information. -
Support for visualization of route progress with the addition of
CompletedRoute
to theNavigationFeedbackResponse
message. -
Prompt
nodes now support custom parameter specification for answers, enabling prompts for any data supported by the Service Customization service. More detailed descriptions of how to specify these parameters can be found in the service customization documentation.
-
Webhooks: Webhooks are a new mechanism for clients to subscribe to real-time Orbit events. In order to receive events, Webhook subscribers must register with Orbit via the settings UI or the new
/webhooks
endpoints documented as part of the Orbit API. Corresponding helper functions such aspost_webhook
are available in bosdyn-orbit's client. -
Scheduler: Alongside the new Orbit scheduler, one can also schedule missions via the new
/calendar
set of Orbit API endpoints. Corresponding helper functions such aspost_calendar_event
andget_calendar
are available in bosdyn-orbit's client.
Spot can now autonomously navigate and localize on Graph Nav maps that have been recorded while using a Global Positioning System (GPS) receiver. Note that the robot does not consume GPS data directly from GPS receivers. Instead, the GPS receiver must be connected to a payload computer (e.g., Core I/O) that is running software that receives the required information from the GPS receiver, then communicates it to the Aggregator Service
using the NewGpsDataRequest
RPC. Extensive documentation is available here; an example is also provided. One thing worth noting is that although the example makes use of NMEA messages, there is no reason the payload computer could not receive configure the receiver to output messages in a different format (e.g., GSOF, UBX, OEM7).
A new enum value, SWING_HEIGHT_AUTO
, has been added to the SwingHeight
enum. This setting results in the swing height being automatically adjusted based upon the current state of the robot and its surrounding environment.
A new enum, DescentPreference
, has been added to the StairData
message. The user may allow the robot to descend the stairs facing forwards by setting DESCENT_PREFERENCE_PREFER_REVERSE
or DESCENT_PREFERENCE_NONE
. This setting can be useful for allowing the robot to descend a staircase where there was not enough room to turn around after the initial descent (e.g., a catwalk).
This feature allows payloads to display live data on the tablet and Orbit during teleoperation. The GetLiveData
RPC has been added to both the Data Acquisition and Data Acquisition Plugin services. Please see the CoreIO Modem Plugin example. Helper functions have been added to signal_helpers.py, unit_helpers.py, and test_signals_helpers.py
. The DataAcquisitionClient and DataAcquisitionPluginService classes have been updated accordingly.
Two RPCs have been added, namely QueryStoredCaptures
and QueryMaxCaptureId
. QueryStoredCaptures
is used to query the Data Acquisition Store Store for stored data while QueryMaxCaptureId
returns only the largest capture ID for the associated query. These RPCs are intended to be used instead of the /v1/data-buffer/daq-data/
endpoint.
- The field,
disable_velocity_limiting
, has been added to theArmCartesianCommand
message. Setting this field totrue
disables protections that prevent the arm from moving unexpectedly fast. Users must exercise extreme caution when setting this field totrue
. - The field,
disable_safety_check
, has been added to theArmImpedanceCommand
message. Setting this field totrue
disables the cancellation of an arm trajectory for unsafe behaviors. Users must exercise extreme caution when setting this field totrue
. - A new enum value,
STATUS_TRAJECTORY_CANCELLED
, has been added to theFeedback
message ofArmImpedanceCommand
. This feedback status indicates whether an arm instability was detected, and if it was detected, the command is cancelled. This new status may be useful for debugging purposes.
A new enum value, NETWORK_COMPUTE_STATUS_ANALYSIS_FAILED
, has been added to the NetworkComputeStatus
enum. If the Network Compute Bridge Worker fails to process the input image for some reason (e.g., it was blurry), the Worker may use this status to indicate that the action should be retried. If the action is part of an autowalk, the retry_count
in the FailureBehavior
message must be > 0.
Our service customization helpers now include more helper functions, including:
- Generation of specs from a set of Python-native objects as arguments. See
make_list_param_spec
for an example. - Conversions to Python-native values for
DictParams
,ListParams
, andOneOfParams
. Seedict_params_to_dict
for an example. - Generation of default parameter values from a parameter spec. See
double_spec_to_default
for an example. - Value coercion, which allows you to gracefully handle errors from parameter values being out of spec. See
int_param_coerce_to
for an example of this, although one is more likely to usedict_param_coerce_to
.
- Added
GetChoreographySequence
RPC to request the full sequence proto with a given name from Spot. - Added
ChoreographyTimeAdjust
RPC to slightly modify the start time of the nextExecuteChoreography
RPC request that will be received by the robot in the future.
Added ResetSafetyStop
RPC for Safety-Related Stopping Function (SRSF) compatible robots. Robots equipped with this feature will be listed as Safety-Related Stopping Function (SRSF) "Enabled" under the hardware information section found in the "About" page on the robot's admin console.
New configuration options have been added to Area Callbacks to specify GraphNav's behavior with respect to blockages, impairment, entities, and stopping poses for callback regions.
Clients are now configured with a default 5s keep-alive time, which triggers a faster reconnect with the service, when the network connection goes down.
Lease update change: ignore failed old leases in the case the wallet contains the new lease.
A new SystemState
message that includes the temperature data for the robot's motors has been added to the RobotState
message. This new message is expected to expand in the future. The documentation for the Kinematic State
message in robot_state.proto has been improved.
The SpotCam CompositorClient now sets both the coords
(deprecated in v3.3) and meter
fields for backwards compatibility purposes in the set_ir_meter_overlay
and set_ir_meter_overlay_async
methods.
In the SpotCam PtzClient, focus_mode
overrides distance
in the set_ptz_focus_state
and set_ptz_focus_state_async
methods, so long as it is not set to None
.
Two new helper functions have been added to the Vec3
class in math_helpers.py, namely to_numpy
and from_numpy
. These functions may be used to convert back and forth between Vec3
and numpy arrays.
The get_info
method in the Mission Client now supports very large missions which would have previously exceeded the maximum protobuf size. If the robot software version is such that the GetInfoAsChunks
RPC is unimplemented, get_info
falls back to the GetInfo
RPC instead.
For non-Core I/O payloads, it is now recommended to authenticate and register payloads by generating a payload credentials file with a unique GUID and secret. The read_or_create_payload_credentials
and add_payload_credentials_file_argument
helper functions assist with doing this. Core I/O Extensions should continue reading the existing on-disk file, located at /opt/payload_credentials/payload_guid_and_secret
.
GraphNav will no longer restart an Area Callback in the middle of a region if it re-routes. It will instead call a new Area Callback RPC to inform the callback of the change.
Published robot state messages previously contained kinematic information for a non-existent HR0 joint on Spot's arm, set to all zeros. This has been removed and the published kinematic information now only contains existing joints. The number of published joints will be one less than on releases < 4.0. Customers storing local copies of Spot URDF files may need to reacquire them from the robot after updating to 4.0.
-
The protos in the
bosdyn-choreography-protos
package have been moved into bosdyn-api;bosdyn-choreography-protos
is now an empty package that just depends onbosdyn-api
. -
The
number_of_steps
in theStaircase
message is deprecated and replaced by the length of thesteps
field in the same message (Staircase
). -
The
pixel_to_camera_space
method in theImageClient
class has been updated such that theimage_proto
argument should now be of typeimage_pb2.ImageSource
(previouslyimage_pb2.Image
). If the method is called with animage_proto
argument of typeimage_pb2.ImageCaptureAndSource
orimage_pb2.ImageResponse
, a warning message is logged. -
Network Compute Bridge: The
object_in_image
in theNetworkComputeResponse
message is deprecated and replaced byobject_in_image
inOutputImage
-
Autowalk: The
root_id
in theElementIdentifiers
message is deprecated and replaced bynavigation_id
in the same message. -
Mission Prompt: The
options
list inPrompt
message is deprecated and replaced by the wrappedOptionsList options_list
field to support answer specification by bothOptionsList options
andDictParam.Spec custom_params
. -
Mission Service: the
impl
field (typegoogle.protobuf.Any
) intype
oneof -
bosdyn.client.robot_id.create_strict_version()
uses deprecateddistutils
functionality. Usebosdyn.client.robot_id.version_tuple()
instead. -
The kinematic_state's transforms_snapshot now uses "arm0.link_wr1" instead of "link_wr1" for the name of the frame attached to the SpotArm's wr1 link. This is (1) the name used in the URDF description of the robot and (2) the name used in the image service snapshots. We will continue to publish the kinematic_state's snapshot with the deprecated name in the 4.0 release, but it will be removed in a future release.
-
bosdyn.client
commandbecome-estop
is deprecated and is now a subcommand underestop
-
The package
bosdyn-scout
is deprecated and replaced with bosdyn-orbit, due to Scout being renamed to Orbit. As a result, the pre-existing examples in../python/examples/scout/
are moved to../python/examples/orbit/
. All examples usebosdyn-orbit
instead ofbosdyn-scout
. -
The
/login
Orbit API endpoint is now deprecated. It has been functionally replaced by the/api_token/authenticate
endpoint. This endpoint allows an admin user to generate an API Access Token with specific permissions for use against the Orbit API. A correspondingauthenticate_with_api_token
helper function in bosdyn-orbit's client has replaced 3.3'sauthenticate_with_password
function. -
The
/missions
set of Orbit API endpoints are now deprecated in favor of the/site_walks
endpoints. Corresponding helper functions such asget_site_walks
in bosdyn-orbit's client support this.
- There are circular imports between bosdyn/api/gps/registration.proto and bosdyn/api/world_object.proto. This may break proto code generation for some languages (e.g., Go).
- The /v1/data-buffer/daq-data/ REST endpoint sometimes fails to return all of the requested data. Two workarounds are to (1) modify the query parameters such that a subset of data is returned or (2) use the new QueryStoredCaptures RPC.
- Same as 3.3.2.
-
Arm Freeze : Command Spot's end-effector to hold a pose expressed in the ODOM and BODY frames, demonstrating the differences of holding a pose relative to and expressed in fixed versus moving frames.
-
Long Arm Cartesian Trajectory: Show how to follow a long cartesian trajectory with the arm.
-
Orbit Schedule Mission: An example to show how to create, edit, and delete a mission calendar event using Orbit web API.
-
Orbit Runs Response: Tutorial to show how to use the Orbit client to get runs response and process data through the Orbit web API.
-
Orbit Send Robot Back to Dock: An example to show how to send robot back to the dock using Orbit web API.
-
Orbit Disable/Enable Calendar Events Based on Weather: An example to show how to enable or disable calendar events based on weather using Orbit web API.
-
Orbit Webhooks: An example to show how to utilize webhooks using Orbit web API to obtain data.
-
SpotCam Video Recording: An example that shows how to record a video using SpotCam.
-
DAQ Plugin with Custom Parameters: An example that shows how to use custom parameters with a DAQ plugin.
-
Reset Safety Stop: An example that shows how to reset the primary and redundant safety stops on a Safety-Related Stopping Function (SRSF) configured robot. Robots equipped with this feature will be listed as SRSF "Enabled" under the hardware information section found in the "About" page on the robot's admin console.
-
Metrics Over CoreIO: An example that shows to upload metrics to Boston Dynamics via CoreIO LTE or WiFi (using a WiFi dongle).
-
View GraphNav Map in a Web Browser: An example that shows how to view a GraphNav map on Open Street Maps in a Web Browser.
-
GPS Listener: An example that shows how to consume data from a GPS receiver and send it to Spot. The example includes configurations for the Trimble SPS986 and Leica GA03 receivers, though any GPS receiver that publishes the required information could hypothetically be used (your mileage may vary based upon the receiver's performance).
-
Extract Images from Walk: An example that shows how to extract all of the record-time images embedded in a .walk and create a .pptx slideshow containing them.
-
Signals CoreIO Modem: An example that gets modem data from the CoreIO and sends it to the robot in such a way (using the Signals API) that it is displayed on the tablet and Orbit in real-time.
-
Extensions: A couple of helper scripts have been introduced to help create CORE I/O and Scout Extensions. These can even be used to package any other Dockerized example into an Extension.
-
Area Callbacks: Updated to set the new callback configuration parameters.
-
Orbit Hello: Updated to use
bosdyn-orbit
instead ofbosdyn-scout
. -
Orbit Export Run Archives: Updated to use
bosdyn-orbit
instead ofbosdyn-scout
. -
Fan Control Mission Service: FanOffServicer now implements GetRemoteMissionServiceInfo, which prevents a harmless message from being printed when the example is run.
-
GraphNav Command Line: Added support for navigating the robot to a given latitude/longitude/yaw. Some new helper functions include
_clear_graph_and_cache
,_navigate_to_gps_coords
,_parse_gps_goal_from_args
, and_navigate_to_parsed_gps_coords
. -
GraphNav View Map: Added two command-line arguments that control whether text for each waypoint and world object should be shown.
-
Arm Impedance Control: Updated to use "arm0.link_wr1" instead of "link_wr1" for the name of the WR1 frame.
-
BDDF Download: Updated documentation to indicate that (at most) 1 hour of data may be requested. If the user requests more than 1 hour, an error is now bubbled up through the GUI.
-
Network Compute Bridge Worker (Fire Extinguisher): The base image in Dockerfile.l4t has been updated to account for v4.0 CoreIO running on Jetpack 5.
-
Network Request Callback: The base image in Dockerfile.coreio has been updated to account for a dependency that requires Python 3.10. NetworkRequestCallbackServicer now implements GetRemoteMissionServiceInfo, which prevents a harmless message from being printed when the example is run.
-
Post-Docking Callback (Cloud Upload): FanOffServicer now implements GetRemoteMissionServiceInfo, which prevents a harmless message from being printed when the example is run.
-
Power Off Mission Service Callback: PowerOffServicer now implements GetRemoteMissionServiceInfo, which prevents a harmless message from being printed when the example is run.
-
Ricoh Theta: The base image in Dockerfile.l4t has been updated to account for v4.0 CoreIO running on Jetpack 5. When no password argument is supplied, the default password for the Ricoh Theta now includes only the numeric portion of the Ricoh Theta SSID (as described in the Ricoh Theta documentation).
-
Custom Parameter Image Server: The base image in Dockerfile.l4t has been updated to account for v4.0 CoreIO running on Jetpack 5.
-
Custom Parameter Network Compute Bridge Worker: The base image in Dockerfile.l4t has been updated to account for v4.0 CoreIO running on Jetpack 5. Specific instructions for how to build the corresponding Spot Extension are now included.
-
Detect and Follow: The base image in Dockerfile.l4t has been updated to account for v4.0 CoreIO running on Jetpack 5. Specific instructions for how to build the corresponding Spot Extension are now included.
-
DAQ Plugin Tester: The plugin now tests for whether the DAQ plugin is publishing live data.
-
Fetch Tutorial: The example has been updated such that it no longer uses the
trajectory_command
method, which has been removed. The base image in Dockerfile.l4t has been updated to account for v4.0 CoreIO running on Jetpack 5. -
Self Registration: Updated to generate and read a unique GUID and secret from a payload credentials file, as is now recommended for payload authentication.
-
Payloads: Updated to generate and read a unique GUID and secret from a payload credentials file, as is now recommended for payload authentication.
-
SpotCam - Opening .pgm/.raw Files: The example code for opening SpotCam .pgm and/or .raw files has been updated to also work for files downloaded from the tablet and/or Scout. Previously, it only worked for files downloaded from the SpotCam.
Mission question answerer (updated)
Several protobuf fields or services are scheduled to be removed in the 4.0 release. Please ensure that they are no longer used within your code.
LogAnnotationService
- Auth application token.
- Robot commands: non-synchronized mobility commands. Top-level feedback messages.
- Graph Nav map edge annotations:
vel_limit
,ground_mu_hint
,grated_floor
- SpotCheck feedback:
foot_height_results
andleg_pair_results
In the upcoming release 4.0, we plan to change the encoding for real-valued fields in local grids to RAW instead of RLE (Run-Length Encoded) and provide client helpers for decoding. Make sure your code handles the encoding
field in LocalGridResponse
correctly.
Updated Data Acquisition system diagram and Network Compute Bridge documentation.
Added LogStatus documentation in the list of robot services.
min_timeout
value in AcquireDataRequest
:
- Added as an argument in Data Acquisition Service SDK client.
- Updated mission service to specify the field in requests to Data Acquisition Service.
- Propagated to RPCs sent to the Image and Network Compute Bridge services.
Added path_following_mode
and ground_clutter_mode
arguments in most_restrictive_travel_params
method in boston.mission
util.py (found here).
Added get_run_archives_by_id
method in Scout client.
The Inverse Kinematics Service is now available on robots without arms. Only body-mounted tools are supported on such robots.
Same as 3.3.0
Log Status: Show how to query the log status service.
Scout Export Run Archives: Show how to export run archives from Scout for the recent completed missions.
Simple Alert Server: Additional Network Compute Bridge worker that generates responses with alerts.
Edit Autowalk: Fixed documentation and improved arguments accepted by the example application so the walk filename is not assumed to be autogenerated.
Fire Extinguisher Network Compute Bridge Worker: Added min_confidence
parameter and fixed output images so they are displayed on the tablet.
Network Compute Bridge: Updated requirements files and docker instructions.
Replay Mission: Fixed documentation and improved arguments accepted by the example application so the walk filename is not assumed to be autogenerated. Updated example to use Autowalk service to load Autowalk missions.
Several protobuf fields or services are scheduled to be removed in the 4.0 release. Please ensure that they are no longer used within your code.
LogAnnotationService
- Auth application token.
- Robot commands: non-synchronized mobility commands. Top-level feedback messages.
- Graph Nav map edge annotations:
vel_limit
,ground_mu_hint
,grated_floor
- SpotCheck feedback:
foot_height_results
andleg_pair_results
Users can make reachability and stance-selection queries for reaching to locations with the arm or pointing a body-mounted sensor. Requests can specify pose or gaze targets for a wrist-mounted or body-mounted tool, with a variety of options for body, arm, and stance configuration. The service responds with a full robot configuration (and frame snapshot including body, feet, and tool) that satisfies the specifications of the request, or an indication that no solution was found.
This service is only available if an arm is attached to the robot.
Use the LogStatus service to start and terminate experiment or retro logs. These logs can be used with Boston Dynamics support to diagnose problems with the robot or its systems.
When writing a service to extend the capabilities of the robot, there are now additional fields and messages to allow the service to specify which and what kind of parameters that the service can accept with its requests. These parameters can be modified by end users via tablet operation or Scout. The services that support this customization are
- Image services
- Data Acquisition plugins
- Network Compute Bridge workers
- Remote Mission callbacks
- Area Callbacks
More detailed descriptions of how to specify these parameters can be found in the service customization documentation.
- Constrained Manipulation: Users can put constrained manipulation in velocity control or position control of the task space. Previously, all constrained manipulation motions were velocity controlled, meaning that users would for example specify the velocity of turning a crank. In position control mode, the user can specify target positions, such as the angle or distance to move the object, as well as acceleration limits to obey. Previously, the internal estimator was always reset with a new request. Now users can disable that resetting, for cases where the task configuration has not changed from the previous request.
- Door opening: Added new
STATUS_STALLED
andSTATUS_NOT_DETECTED
error statuses, andDoorCommand.Feedback
reports progress through the door. - Gripper Camera: New options added for controlling white balance, gamma, and sharpness.
- Added many pieces of information to
ArmImpedanceCommand.Feedback
.
No-Go Regions: Added the ability to apply user-defined rectangular obstacles to the foot and body obstacle maps.
A user can define rectangular regions in which the robot should not step, and/or rectangular regions the body should not enter, in addition to the standard obstacle mapping.
By default, a User No-Go Region will add both a body obstacle, and a slightly expanded footstep obstacle to the respective obstacle maps. If this default behavior is not desired there are optional flags to designate the User No-Go Region as just a body obstacle or just a foot obstacle instead of both, and to remove the extra padding on the foot obstacle.
These regions are added via the World Object Service, which now includes an object_lifetime
field with the duration after which the obstacle expires.
Area Callbacks can raise a PathBlocked
error to indicate that the region is blocked and graph nav should re-route.
Area callbacks that control the robot through the region can now update the localization to the end of the region when they have successfully moved the robot through the region so that Graph Nav does not try to re-navigate the region.
Uploading Graphs has more validation steps and will report STATUS_INVALID_GRAPH
under more scenarios. There is a new ValidationStatus
to show the results of this process. Recoverable graph problems will not cause the load to fail, but will instead be reported as "warnings" in the ValidationStatus
message.
Topology Processing (auto loop closure) is now much less aggressive about creating loop closures and will make fewer and better loop closures than before, with the exception of waypoints near docks which are more forgiving (to allow the robot to get back to the dock from more locations).
If the robot gets stuck, it will report a "stuck reason" indicating which kind of failure resulted in getting stuck.
Added a new ChoreographyCommand
RPC to support interactive choreography moves.
Added a new ChoreographyStatus
RPC so that users can receive feedback on the dance state a robot is in and a robot’s progress in completing a dance or current move(s) in a dance.
- Added
exit_state
field inSequenceInfo
message to specify the exit transition state of the sequence. - Added
execution_id
field inExecuteChoreographyResponse
message with the unique ID for the execution. - Added
id
field inMoveParams
message, set by the client or auto-assigned by the service, to be reported in theChoreographyStatusResponse
ActiveMoves
field. - Added
custom_gait_params
andleg_joint_params
fields inMoveParams
object. - Added
is_looping
field inMoveInfo
message. - Added
entrance_state
field inChoreographySequence
message to specify an explicit entrance state in the case where the first legs-track move accepts multiple entrance states. - Animations now support more flexibility to adjusting timing, can specify whether the animation starts from a sit pose, or can specify that an Animation can be used for a custom gait.
New fields in the Payload proto enable a liveness check, similar to a service liveness check. The robot will periodically try to ping (ICMP) the payload to see if it is still connected.
liveness_timeout_secs
: How long payload can be unpingable before a liveness fault is raised.ipv4_address
: Address for the robot to ping the payload at.link_speed
: Expected ethernet speed negotiated.
If present, the ipv4_address
field will also be used to detect whether a payload is mounted to the front or rear payload port. If a payload preset has a label "mount_port:rear" and the payload is connected to the front port, it will not be displayed on the registration page. The same is true if there is a preset "mount_port:front" and the payload is connected to the rear port.
Added the SpotCamAlignment action wrapper for aligning Spot Cam image captures.
Images can be stored for Data Acquisition and RemoteGrpc elements in order to aid in editing walks.
Updated the IrMeterOverlay
Spot Cam message and added a new RPC to get the current overlay.
Added new RPCs for setting and getting the focus state of the Spot Cam PTZ.
Added exposure settings to the StreamParams
message.
New AvailableModels
message to describe Network Compute Bridge models available for data acquisition capture.
New unique id
returned in Store*
responses from the DataAcquisitionStore
service. This id can be used in a DataIdentifier
to uniquely identify a particular piece of stored data.
ClearBehaviorFault
echos back the behavior fault if it was active at the time of request.ClearBehaviorFault
specifies a list of blocking hardware faults for an unclearable behavior fault.- An absolute desired position and orientation of the robot’s body origin can now be specified when standing.
- Users can override the configured Leases and Params when issuing an Autoreturn
StartRequest
. - A new
ImpairedStatus
value indicates when the entity detector (required for certain new avoidance behaviors) is not working.
- Mission blackboard state is now reported in the
NodeState
message. GraphNavClient.set_localization_full_response
added to return the full response.RecordingClient.start_recording_full
added to return the full response.- The Robot object has
get_cached_hardware_hardware_configuration()
for checking the hardware configuration efficiently. - The Robot object has an explicit
shutdown()
to stop any background threads it may be running. - World objects can be added or deleted in bulk using the
send_add_mutation_requests()
andsend_delete_mutation_requests()
helpers. - Uploading Graphs has more validation steps and will report
STATUS_INVALID_GRAPH
under more scenarios. There is a newValidationStatus
to show the results of this process. Recoverable graph problems will not cause the load to fail, but will instead be reported as warnings in theValidationStatus
message. - Some mission RPCs could fail due to response message size limits when missions become very large. Newly added RPCs (LoadMissionAsChunks2, GetInfoAsChunks, GetMissionAsChunks) use streaming responses that are assembled into the proper response.
The Python SDK now requires protobuf >= 3.19.4
The following will continue to work, but have been deprecated and may be removed in a future release.
The NetworkComputeBridge Worker service has been re-worked to be more straightforward and provide additional options. The NetworkCompute
RPC is deprecated from the NetworkComputeBridge Workers services; use the new WorkerCompute
RPC instead.
When calling the NetworkComputeBridge service, the input_data
is deprecated in the NetworkComputeRequest
message; use input_data_bridge
instead. When using the input_data_bridge
input, the following changes will apply to the NetworkComputeResponse
output:
- Deprecated
image_response
field; useimage_responses
instead. - Deprecated
image_rotation_angle
field; The worker should handle rotation on its own. - Deprecated the
alert_data
field; usealert_data
inOutputImage
instead. - Deprecated
roi_output_data
field; support for non-image products will be added in a future release.
GripperCameraParam: Renamed CameraMode
enum values.
Graph Nav: The StraightStaircase
representation of staircases is deprecated and replaced with the new StaircaseWithLandings
.
Choreography; The precise_timing
in Animation
message is deprecated and replaced by the more fine-grained control of timing_adjustability
field.
Leases: Use is_stale
instead of the stale time in the LeaseResource
message to determine staleness.
BaseClient.chunk_message
has been moved to the data_chunk
module, along with other serialization functions.
BaseClient.request_trim_for_log
and BaseClient.response_trim_for_log
are deprecated with no replacement. Logging should use regular %-based formatting, rather than prematurely forcing serialization.
When the robot loses connection with an E-stop endpoint, an attempt to power on the robot will now return STATUS_KEEP_ALIVE_MOTOR_OFF
instead of STATUS_ESTOPPED
. In python code it will raise the KeepaliveMotorsOffError
exception instead of EstoppedError
.
Some malformed Graph Nav graphs were previously accepted, but would leave the service in a bad state. These graphs are now explicitly rejected during upload.
When a network transport failure occurs, depending on the particular operating system and version of gRPC installed, the error from the python SDK may not always be the most specific error possible, such as UnknownDnsNameError
. It may instead be raised as either a generic RpcError
, or another generic failure type such as UnableToConnectToRobotError
.
If you write a custom data acquisition plugin or image service, do not change its DataAcquisitionCapability
or ImageSource
set once it is running and registered. New capabilities may not be detected, and old capabilities may still be listed as available in the Data Acquisition service. To change the capabilities of a service: unregister it from the directory, wait until its capabilities are no longer listed in the Data Acquisition service, and then re-register it. This waiting also applies to restarting a service if its capabilities will be different upon restart.
If you write a custom data acquisition plugin without using our helper class, its GetStatus()
RPC is expected to complete immediately. If it takes too long to complete it can cause timeouts when requesting GetStatus()
of the data acquisition service.
If you register a new service with the robot, calling robot.ensure_client()
to create a client for that service may result in a UnregisteredServiceNameError
.
- Workaround: call
robot.sync_with_directory()
beforerobot.ensure_client()
SE2VelocityLimits require care. Correct usage of the SE2VelocityLimit
message requires the user to fully fill out all the fields, setting unlimited values to a large number, say 1e6.
Velodyne client API example has python/matplotlib issue and it needs PyQt5
- Workaround: run
pip install pyqt5
in the venv to get it to work.
Robot command feedback response incorrect with multiple clients running in the configuration with a Mission client sending synchro arm commands with body lease and a Localnav client sending synchro mobility command with mobility lease. In this case, sending both robot command requests and robot command feedback requests, messes up the feedback request for the mission client. It was receiving feedback for the mobility request, and not the arm request.
CustomParam validation will fail if extra parameters are provided that are not in the spec.
Arm Grasp Carry Overrides: Show how to set grasp and carry overrides for Spot Arms.
Arm Impedance Control: Show how to send arm impedance commands to the robot.
Arm WASD: Create an interface for controlling the arm with your keyboard.
Inverse Kinematics: Show to interact with the Inverse Kinematics Service.
Network Request Callback: Provide a callback that queries a network endpoint and then checks if the response contains a particular string.
Record Autowalk: Create an interface for recording an Autowalk with your keyboard.
Scout - Hello Scout: Introductory programming example for the Scout client, which uses the Scout web API.
Service Customization for Image Services: Show how to host an image service that contains an image source with custom parameters.
Service Customization for Network Compute Worker Services: Show how to host a Network Compute Bridge Worker service that contains custom parameters.
User Nogo Region: Show how to add and delete user no-go regions to create user-defined body and/or foot obstacles using the World Object service.
Area_callback: Added lease_client.take()
call.
Arm_constrained_manipulation: Improved documentation, introduced the position control loop for constrained manipulation and fixed bugs in setting position and velocity variables.
Arm Impedance_Control: Added impedance feedback.
Estop: Added feedback in GUI.
Gripper Camera Params: Made all gripper camera parameters configurable.
Hello_spot: Updated body control command.
Replay Mission: Split timeout parameter into upload timeout and mission timeout.
- Added compositor get/set reticle calls.
- Removed network settings calls.
- Added get/set ptz focus calls.
- Added
exposure_mode
andexposure_duration
inStreamQualityCommand
.
- Added documentation for running it as a Spot Extension.
- Added authentication through payload credentials.
Payloads: Updated example to work with robots that do not have an arm.
Remote Mission Service: Updated example to use custom parameters.
No changes from 3.2.2.
Improved CORE I/O documentation on passwords, user specifications in Spot Extensions, and ports for incoming traffic.
Updated Data Acquisition Tutorial documentation on udev rules to reflect changes on the automatic execution of udev rules during a Spot Extension installation.
Same as 3.2.0
Updated Nvidia base docker image version in Dockerfile of the following:
- Fetch tutorial,
- Crosswalk Lights and Look Both Ways Area Callback examples,
- Fire Extinguisher Detector Network Compute Bridge worker example,
- Ricoh Theta example
Updated Fire Extinguisher Detector example to work with the updated tensorflow version installed in the updated nvidia base docker image.
Fixed issues relating to GraphNav Area Callbacks and loop closures where connections could be made in the middle of an Area Callback. These connections are now prohibited. Maps with incorrect connections must be re-recorded or reprocessed with the map processing service to re-create better loop closures.
Updated Fetch tutorial with information to run on CORE I/O payload.
Added Getting Started section in Scout documentation.
Removed unused imports in the protobuf files protos/bosdyn/api/autowalk/walks.proto
, protos/bosdyn/api/graph_nav/area_callback.proto
, protos/bosdyn/api/graph_nav/graph_nav.proto
, protos/bosdyn/api/mission/nodes.proto
.
Autowalk missions:
- Added flag for skipping actions.
- Added action duration field.
Fixed a bug in our Vec3
cross product in python/bosdyn-client/src/bosdyn/client/math_helpers.py
Same as 3.2.0
Replay Mission: Updated example to point to correct mission file.
Velodyne Client: Fixed velodyne client PyQt dependency issue.
Enables API clients to specify high level autonomous behaviors for Spot using an easily editable format. The autowalk format is a list of actions and their associated locations. Using this service, users can program the robot to “go to location A, perform action A, go to location B, perform action B, etc.”. The autowalk service compiles the autowalk into a behavior tree that can then be uploaded to the robot and played using the mission service. Previously this feature was only available on the tablet, but now it is a service for all client applications.
Enables users to specify virtual springs and forces about the end effector. Users can specify a trajectory that the hand (or something attached to the hand) should follow while being dragged along by those springs. They can also add an additional feed-forward wrench (force + torque) that the end effector can apply. This command can be useful for tasks such as inserting a peg into a hole, or sliding along a surface.
Notes:
- This is a beta release, so care should be taken when specifying parameters, as damage to the robot or the surrounding environment may occur.
- Currently the maximum stiffness achievable with an impedance command is less than an ArmCartesianCommand, so if high positioning accuracy is required, ArmCartesianCommand or ArmSurfaceContact should be used.
Enables users to register a callback that is called in certain areas of the map during navigation. These “Area Callbacks” can instruct the robot to wait until the area is safe to cross (such as a crosswalk), take control of the robot and perform an action (such as opening a door), or perform a background action while in a certain area of the map (such as flashing lights or playing sounds). This enables integration with the Graph Nav navigation system to extend its capabilities in terms of safety and new actions while navigating. See the Area Callback documentation for more details.
Fan Commands request the robot to power the fans to a certain percent level (0 being off, 100 being full power) for a certain duration, for use cases such as temporarily turning the fans off during an audio recording. A fan command being accepted does not guarantee that it will work for its entire duration, for cases such as the robot ran too hot and therefore took back control of the fans, or another fan command was overrode the existing fan command.
When this feature is enabled, the robot will treat low objects (shorter than 30cm height) as obstacles during mission playback. The robot will only be willing to step up or down onto different surfaces if it had stepped on them during mission recording. This mode may cause the robot to take unexpected turns in some environments if the robot perceives small objects (real or imagined). Very small objects (e.g. extension cords) will likely still be ignored by the robot.
CORE I/O payload replaces the Spot CORE payload. We added the documentation related to the new features in CORE I/O in here
CORE I/O contains improved functionality to package and run applications as Spot Extensions. We added the Spot Extensions documentation here
Choreography API:
- Deprecated
known_sequences
and addedSequenceInfo
with the list of choreography sequences the robot knows about. - RPC additions:
DeleteSequence
: Delete the retained file for a choreography sequence so the sequence will be forgotten on reboot.SaveSequence
: Write a choreography sequence as a file to robot memory so it will be retained through reboot.ModifyChoreographyInfo
: Edit the metadata of a choreography sequence and update any retained files for that sequence with the new metadata.ClearAllSequenceFiles
: Reset to a clean slate with no retained files by deleting all non-permanent choreography related files.
Added full ImageRequest
in data_acquisition request and deprecated image_source
and image_format
fields.
Docking:
- Added UpdateDockingParams in DockingCommandFeedbackRequest to update parameters relating to the specified command ID.
- Added
STATUS_ERROR_STUCK
inDockingCommandFeedbackResponse
to flag the robot not making progress towards docking.
Added Matrixf
, MatrixInt64
, MatrixInt32
and Vector
in geometry.proto
.
GraphNav:
graph_nav.proto
:- Added refinement field in GraphNav’s
SetLocalizationRequest
as a choice of refining fiducial results with ICP or with visual features. - Added
STATUS_VISUAL_ALIGNMENT_FAILED
in SetLocalizationResponse to flag the visual feature based alignment failing or the pose solution being considered unreliable. - Added
path_following_mode
,blocked_path_wait_time
andground_clutter_mode
in GraphNav’sTravelParams
. - Added definitions to support the new Area Callbacks feature.
- Added
route_following_status
inNavigationFeedbackResponse
with additional information about what kind of route the robot is following and why. - Added
blockage_status
inNavigationFeedbackResponse
with additional information about whether or not the robot believes the current route to be blocked. - Added
ValidateGraph
RPC to run a check on the currently loaded map.
- Added refinement field in GraphNav’s
map.proto
:- Added optional
ClientMetadata
field with information to attach to waypoints that are being recorded. - Added
robot_id
field with information of the robot that created this waypoint andrecording_started_on
field with information about when the recording session started in robot time basis inWaypointSnapshot
. - Added
path_following_mode
,disable_directed_exploration
,area_callbacks
,ground_clutter_mode
toEdge
definition.
- Added optional
recording.proto
:- Added
STATUS_ROBOT_IMPAIRED
inStartRecordingResponse
to flag the robot being unable to start recording because it is impaired - Added
STATUS_ROBOT_IMPAIRED
inStartRecordingResponse
with information on why the robot is impaired. - Added
status
andimpaired_state
fields inGetRecordStatusResponse
with information on whether the robot is impaired.
- Added
Missions:
mission.proto
:- Added
severity
field inQuestion
with the severity of the question. - Added
path_following_mode
andground_clutter_mode
inPlaySettings
with information on whether to use default or strict path following mode and whether or not to enable ground clutter avoidance, and which type.
- Added
nodes.proto
:- Added
Switch
node definition in mission definition to run a specific child based on a specified pivot_value. - Added
respect_child_failure
flag in missionRepeat
nodes to control whether a repeat node will keep running its child regardless of whether or not the child succeeds or fails. BosdynRecordEvent
message:- Added
succeed_early
to control the wait for theRecordEvents
RPC. - Added
additional_parameters
to support runtime parameters.
- Added
RemoteGrpc
message:- Added
severity
field to determine what sort of alerting a prompt triggers. - Added
BosdynGripperCameraParamsState
message to get the state of the gripper camera params from the robot. - Added
SetGripperCameraParams
message to set gripper camera params. - Added optional variables
cleared_cause_fall_blackboard_name
,cleared_cause_hardware_blackboard_name
andcleared_cause_lease_timeout_blackboard_name
inFormatBlackboard
message to store cleared behavior faults.
- Added
- Added
Network Compute Bridge:
- Updated
ImageSourceAndService
field inNetworkComputeRequest
to be a choice between existingimage_source
field and a more completeImageRequest
field with all the image requests field. - Added
output_images
field inNetworkComputeResponse
to output images generated by a model.
Added stair_mode
field in MobilityParams
with selected option for stairs mode.
Spotcheck:
- Added
STATE_ARM_JOINT_CHECK
inSpotCheckFeedbackResponse.State
message for arm joint endstops and cross error check being underway. - Added
ERROR_ARM_CHECK_COLLISION
andERROR_ARM_CHECK_TIMEOUT
enum values inSpotCheckFeedbackResponse.Error
to flag an arm motion causing collisions (e.g. w/ a payload) or timeout during arm joint check. - Added
ERROR_ENCODER_SHIFTED
andERROR_COLLISION
enum values inJointKinematicCheckResult.Error
to flag whether the measured endstops shifted from kin cal or the joint would have a collision. - Added
STATUS_CALIBRATION_VERIFICATION_FAILED
enum inCameraCalibrationFeedbackResponse.Status
to flag Spotcheck failed after the camera calibration.
Improved Choreography documentation with 3.2 functionality and API changes.
Updated the lease usage in the Fetch tutorial.
Updated the Data Acquisition Tutorial documentation with information on how to convert the tutorial into a Spot Extension to run on the CORE I/O.
Added documentation on thermal SpotCAM images here.
Added AutowalkClient
to support the new Autowalk functionality
Added LoggingHandler
class in data_buffer.py
as a logging system Handler that will publish text to the data-buffer service
Added InvalidGravityAlignmentError
error in map_processing.py
to report if one or more anchoring hints disagrees with gravity.
Updated PayloadRegistrationKeepAlive
to catch TooManyRequestsError
exceptions and continue on in such cases.
Added fan power control/feedback methods in python PowerClient; also added FanControlTemperatureError
to report current measured robot temperatures are too high to accept user fan commands.
Added RobotImpairedError
in Python GraphNavRecordingServiceClient
to report failures to start recording because the robot is impaired.
Added sync_with_services_list
in robot.py
as an alternate version of sync_with_directory
that takes the list of services directly and does not perform any RPCs.
Added update_secure_channel_port
in robot.py
to update the port used for creating secure channels, instead of using the default 443
Added payload_estimation_command
method in robot_command.py
to get the robot estimate payload mass.
Added exc_callback
function as an argument in ResponseContext
in server_util.py
to be called with exception type, value, and traceback info if an exception is raised in the body of the "with" statement.
Added CameraSpotCheckTimedOutError
, CameraSpotCheckFeedbackError
and CameraCalibrationResponseError
in spot_check.py
as errors for timing out waiting for SUCCESS response from camera spot check, general class of errors for camera spot check feedback and general class of errors for camera calibration routines, respectively.
Updated RemoteClient
to use lease processors and lease wallet when not given explicit leases.
Added _build_establish_session_request
and _build_tick_request
helper functions in remote_client.py
.
Added lease_resource_hierarchy.py
with helper functionality for managing hierarchy of lease resources.
Added lease_validator.py
with functionality to track lease usage in intermediate services.
Added spot_cam/lights_helper.py
with helper functionality to control SpotCAM lights.
Deprecated Choreography API known_sequences
; use new SequenceInfo
instead.
Deprecated image_source
and image_format
fields in DAQ requests and added full ImageRequest
instead.
The boolean field stair_hint
is deprecated from MobilityParams
and it has been replaced by the field stairs_mode
.
Deprecated LogAnnotationHandler
; use bosdyn.client.data_buffer.LoggingHandler
instead.
safe_power_off
method is deprecated in PowerClient
and replaced by the less ambiguous safe_power_off_motors
function.
Removed _should_send_app_token_on_each_request
method in robot.py
.
Deprecated Spot CORE Documentation and moved to Pre-3.2 Spot CORE Documentation.
When a network transport failure occurs, depending on the particular operating system and version of gRPC installed, the error from the python SDK may not always be the most specific error possible, such as UnknownDnsNameError
. It may instead be raised as either a generic RpcError
, or another generic failure type such as UnableToConnectToRobotError
.
If you write a custom data acquisition plugin or image service, do not change its DataAcquisitionCapability
or ImageSource
set once it is running and registered. New capabilities may not be detected, and old capabilities may still be listed as available in the Data Acquisition service. To change the capabilities of a service: unregister it from the directory, wait until its capabilities are no longer listed in the Data Acquisition service, and then re-register it. This waiting also applies to restarting a service if its capabilities will be different upon restart.
If you write a custom data acquisition plugin without using our helper class, its GetStatus()
RPC is expected to complete immediately. If it takes too long to complete it can cause timeouts when requesting GetStatus()
of the data acquisition service.
If you register a new service with the robot, calling robot.ensure_client()
to create a client for that service may result in a UnregisteredServiceNameError
.
- Workaround: call
robot.sync_with_directory()
beforerobot.ensure_client()
SE2VelocityLimits require care. Correct usage of the SE2VelocityLimit
message requires the user to fully fill out all the fields, setting unlimited values to a large number, say 1e6.
Python wheels 3.1.2.1 and 3.2.0 do not work on nvidia docker image nvcr.io/nvidia/l4t-tensorflow:r32.6.1-tf2.5-py3
.
- Workaround: Use
nvcr.io/nvidia/l4t-tensorflow:r32.7.1-tf2.5-py3
as the base image instead.
Velodyne client API example has python/matplotlib issue and it needs PyQt5
- Workaround: run
pip install pyqt5
in the venv to get it to work.
Robot command feedback response incorrect with multiple clients running in the configuration with a Mission client sending synchro arm commands with body lease and a Localnav client sending synchro mobility command with mobility lease. In this case, sending both robot command requests and robot command feedback requests, messes up the feedback request for the mission client. It was receiving feedback for the mobility request, and not the arm request.
Binary files are not handled correctly in git when cloning SDK on Windows The failure is due to a random string of bytes mapping to \n
in the binary protobuf getting converted to ^M
(CRLF) in Windows.
Area Callback: Example with a Crosswalk Area Callback action
Arm Impedance Control: Example for how to send arm impedance commands with the robot
CORE I/O GPIO: Example to demonstrate how to use the CORE I/O GPIO pins to blink an LED
Edit Autowalk: Example on how to edit and replay an Autowalk via the API
Fan Commands: Example to provide a basic Python script to call and receive feedback on a fan command and provide a usable template for writing a callback that issues and blocks during a fan command.
Docking: Added undock function.
Fiducial Follow: Updated example for better lease usage.
GraphNav Command-Line: Fixed lease usage.
Mission Recorder: Added metadata for the recording session.
Network Compute Bridge: Added configuration to create a Spot Extension with the example.
Post Docking Callback: Added configuration to create a Spot Extension with the example.
Remote Mission Callback: Updated example to use lease processors and lease wallet when not given explicit leases.
Replay Mission: Added strict_mode option to use strict path following mode and cleaned up lease use.
- Fixed SpotCAM
webrtc
client reliance on CLI credentials. - Added spotcam ir meter example into command line.
- Hardcoded dependency versions that work with Python 3.6.
Spot Detect and Follow: Added configuration to create a Spot Extension with the example and various improvements.
Stitch Front Images: Add live viewer to example.
The bosdyn-api
and bosdyn-choreography-protos
packages have been rebuilt to support the latest protobuf
package. They now require a minimum protobuf
version of 3.6.1.
Added payloads and lidar transform in GraphNav's WaypointSnapshot
to help with:
- Not getting lost when a big payload occluded the lidar.
- Determine which payloads were used to record a map.
Same as 3.1.0
Same as 3.1.0
Network Compute Bridge (updated) Modified server to use user confidence value as a threshold for returning detections
To improve safety when operating on stairs, the robot may now autonomously walk off staircases in scenarios where it may have previously entered a sit. In the event of communication loss, critically low battery state of charge, or a Safe Power Off Request, the robot will walk off the staircase before sitting and powering off. The direction of travel will generally be to descend the stairs unless the robot has already reached the top landing. This includes automatic sit-and-power-off cases such as from low battery or the E-stop SETTLE_THEN_CUT
level, as well as any client SafePowerOff commands. It does not affect immediate power cut cases such the PowerOff command or the E-stop CUT level.
To override this behavior for SafePowerOff commands, there is a new unsafe_action field in SafePowerOffCommand
which can be set to UNSAFE_FORCE_COMMAND
to force the command to take place immediately. To override this behavior for E-stop or battery power off, set the disable_stair_error_auto_descent
field in the mobility params for the robot commands.
As part of this change, a new TerrainState
message in RobotState
contains the is_unsafe_to_sit
value to report when the robot considers the terrain unsafe to sit on.
The behavior of the robot and leases is changed when the lease owner fails to retain the lease. Prior to 3.1, the robot would sit down and power off, and the lease would be revoked. This behavior allowed a new owner to smoothly take control of the robot in the case that a previous owner left without first returning the lease, but has proved to be frustrating when short comms losses trigger this behavior.
Starting in 3.1, failing to retain the lease will cause the lease to become “stale”. If the lease is stale, another client can acquire the lease and begin using the robot. However, if the original owner returns and begins retaining the lease or sending commands before another client acquires ownership, the lease will become “fresh” again without the original owner needing to re-acquire the robot. This staleness is reported via the new stale_time
field in the LeaseResource
message.
This change means that the robot will no longer sit down and power off if the lease owner disappears. For clients that still want that behavior, it is recommended to use an E-stop endpoint with the owner (which is already the common case), so that a comms interruption will cause the robot to sit and power off via the E-stop system.
A new tutorial provides a walk-through of integrating new sensors with the data acquisition system. It explains how to write, deploy, and use image services and data acquisition plugins with Spot, and how to process the resulting data.
In addition to images and data capabilities, DataAcquisitionRequests can specify network compute actions to perform on captured images by adding a NetworkComputeCapture in the acquisition request list. This capture will save the image and any computed data from the network compute response. This currently only operates on images and will only save the data returned in the response. For use cases that require sending other input data or saving other kinds of output data, it is still recommended to implement a data acquisition plugin to do that work.
Robot image services now report which image formats and pixel formats they support via new fields in the ImageSource
message. When requesting images, clients can specify a desired pixel format, and also a resize ratio. These options allow for reduced bandwidth in cases where the client only needs a smaller image or a grayscale image. New status errors STATUS_UNSUPPORTED_PIXEL_FORMAT_REQUESTED
and STATUS_UNSUPPORTED_RESIZE_RATIO_REQUESTED
can now be returned if the client makes a request that is unsupported. User image services should also report the options they support. The VisualImageSource
constructor now includes an optional argument for a list of supported pixel formats.
A new AlertData message has been added for the purpose of triggering live alerts for various events that can happen during a mission. These alerts can be saved into the DataAcquisitionStore
service using the new StoreAlertData
RPC and queried using the ListStoredAlertData
RPC. Additionally, the alert data can be added to the response from a network compute bridge worker, where it will be automatically saved into the data acquisition store when captured as part of a data acquisition request. If a client calls the network compute bridge service itself, the alert data will be returned to the client in the response but not automatically saved to the data acquisition store.
GripperCameraParamService – Set or query various modes and options on the camera in the robot’s gripper.
RayCastService – Find intersections between a ray and the robot’s representation of the environment.
The Self-Right command now provides feedback in the SelfRightCommand.Feedback
message as to whether it has successfully completed.
When Stand commands come to rest at their final pose, they will now enter a “frozen” state with locked joints. This keeps the robot more stationary for sensor data collection. Disturbances will still cause the robot to adjust and react to recover its position. The status of this “frozen” state is provided by the new StandingState
enum in StandCommand.Feedback
.
A new option, enable_robot_locomotion
has been added to ConstrainedManipulationCommand.Request
. When set to true, the robot will take steps to keep the hand in the workspace during a constrained manipulation command.
A new message, BodyAssistForManipulation
, has been added to the BodyControlParams to allow clients to specify whether the body height or yaw should be used to assist the arm in manipulation. This new option cannot be used together with body offset trajectories specified in the base_offset_rt_footprint
field.
-
image.depth_image_to_pointcloud()
to convert depth images to numpy point clouds. -
image_service_helpers.convert_RGB_to_grayscale()
to convert color images to grayscale. -
math_helpers
now includesVec2
andVec3
objects. -
robot_command.arm_joint_move_helper()
constructs RobotCommands for joint trajectories. -
robot_command.blocking_sit()
androbot_command.blocking_selfright()
command sit and self-right commands and block until they complete. -
robot_command.block_for_trajectory_cmd()
will block until the feedback for a given body trajectory command indicates that it is complete. -
util.add_payload_credentials_arguments()
adds a–payloads-credentials-file
argument that can be used in place of the–guid
and–secret
arguments. This simplifies deployment to payload computers that contain a file with the correct credentials. -
util.read_payload_credentials()
reads payload GUID and secret values from a file for use with payload registration and authentication. -
util.get_guid_and_secret()
is a helper that will return the guid and secret, regardless of if the user used–guid
and--secret
or--payload-credentials-file
. -
world_object.draw_sphere()
andworld_object.draw_oriented_bounding_box()
can be used to set objects in the world object service for debugging purposes.
A new ListAllSequences
RPC allows clients to list all of the available sequences that are known to the robot and can be executed.
A new node type, ClearBehaviorFaults
will allow a mission to autonomously clear behavior faults when desired.
In the python client library the LeaseKeepAlive context manager continually sends RetainLease commands to the robot to keep ownership of a lease. It has been upgraded to support more complete lease management by acquiring the lease if it is not owned when created and an option to return it when it exits. To preserve backwards compatibility, the initial acquisition is allowed to fail, and it does not return it by default. There are two options that control this behavior: must_acquire=True
means that any exceptions that are raised during acquisition are not caught and are raised to the code creating the keep-alive, and return_at_exit=True
means that the lease will be returned when exiting or shutting down the keep-alive. Both of these options default to False
currently.
Arm joint trajectories now include self-collision avoidance to prevent hitting the body or payload with the arm.
The DockProperties of the docks from the World Object Service have an additional from_prior
field that can indicate when that particular object comes from prior map knowledge and was not directly detected. Docking Feedback includes a new failure case STATUS_ERROR_UNREFINED_PRIOR
, for situations in which the dock prior could not be confirmed as a real dock.
Certain commands may be unavailable when the robot is docked (such as rolling over to change the battery). In those cases, the command response will fail with the new STATUS_DOCKED
.
Many gRPC services on the robot have now enabled support gRPC compression, which will be used if the client gRPC library supports it.
The bosdyn.client
metrics
command will print the metrics correctly again.
When localizing to a graph nav map, the SetLocalization
, UploadGraph
, and UploadWaypointSnapshot
RPCs can fail with the new STATUS_INCOMPATIBLE_SENSORS
if the map was recorded using a different sensor setup than the robot currently has onboard. For example, if the map was recorded with a lidar scanner, and the robot does not currently have one equipped. For UploadWaypointSnapshot
, the new status enum will not be known to clients using older versions of the SDK and thus they will not recognize it as an error.
The new SensorCompatibilityStatus
in the responses will report whether the map and/or robot have lidar data for these error cases.
Clearing the map when in the middle of recording would break the recording process. Requesting to clear the map in this case will now return STATUS_RECORDING
. Clients using older versions of the SDK will not know about this new status field and will not treat it as an error case.
Spot Check now has two extra states that it can report being in: STATE_GRIPPER_CAL
and STATE_SIT_DOWN_AFTER_RUN
. It also has two extra error types it can detect and report: ERROR_GRIPPER_CAL_TIMEOUT
as a top-level error and ERROR_INVALID_RANGE_OF_MOTION
for joints.
Automatic data buffer logging of gRPC messages is deprecated. The gRPC messages will continue to be available for download via HTTP in 3.1, but support will be removed in a future release.
FollowArmCommand’s disable_walking
is deprecated. To reproduce the robot's behavior of disable_walking == true
, issue a StandCommand setting the enable_body_yaw_assist_for_manipulation
and enable_hip_height_assist_for_manipulation
MobilityParams to true. Any combination of the enable_*_for_manipulation
are accepted in stand giving finer control of the robot's behavior.
When commanding door opening, the options SWING_DIRECTION_INSWING
and SWING_DIRECTION_OUTSWING
have been renamed to SWING_DIRECTION_PULL
and SWING_DIRECTION_PUSH
.
The signature of CameraInterface.image_decode()
for user image services has changed from passing individual parameters such as image_format
and quality_percent
to directly passing in the image request proto. This change makes it easier to add new options to image requests without breaking existing image service implementations. Services can access the previous parameters via the image request proto, as well as accessing new parameters such as pixel_format
and resize_ratio
.
The –username
and –password
command line options are deprecated in the Python SDK. There are security concerns with using usernames and passwords on the command line. Instead of using bosdyn.client.util.add_common_arguments(parser)
we recommend using bosdyn.client.util.add_base_arguments(parser)
which will not include those options, and then authenticating via bosdyn.client.util.authenticate(robot)
, which will read from the BOSDYN_CLIENT_USERNAME
and BOSDYN_CLIENT_PASSWORD
environment variables. The bosdyn.client
and bosdyn.client.bddf_download
programs will continue to support the old options for now but usage should be switched to the environment variable method instead.
We have changed the LeaseKeepAlive helper to handle more of the lease life-cycle management, where it can acquire and return the lease itself. However, we have kept its default behavior largely unchanged for now to not break existing code. In a future release we may change the defaults for return_at_exit
and must_acquire
to True
. Applications that desire the previous behavior should explicitly set must_acquire
and return_at_exit
to False
to preserve that behavior across a change in the defaults.
The DARK
option for auto white balance for the Spot CAM stream has been deprecated.
The original names still exist, but are deprecated.
bosdyn.client.graph_nav.UnrecongizedCommandError
has been renamed to bosdyn.client.graph_nav.UnrecognizedCommandError
.
bosdyn.bddf.message_reader.channel_name_to_series_decriptor()
has been renamed to bosdyn.bddf.message_reader.channel_name_to_series_descriptor()
The from_obj()
methods on the math helper classes have been renamed to from_proto()
.
Because leases are no longer revoked when the owner fails to check in, there are two changes that must be accounted for:
- The robot will not automatically sit down and power off if the owner times out. It will still sit down and power off if an E-stop endpoint times out. For use cases that want the owner’s absence to cause the robot to sit and power off, make sure that the owner is also maintaining an E-stop endpoint.
- Any client calling
ListLeases
to try to determine if the robot is owned will need to check thestale_time
of theLeaseResource
. Instead of callingListLeases
beforeAcquireLease
, we recommend just callingAcquireLease
first, and reacting to anySTATUS_RESOURCE_ALREADY_CLAIMED
status in the response.
The new safety features to avoid powering off and sliding down stairs means that there is a behavioral change to SafePowerOff commands, powering off due to low battery, and powering off due to an E-stop LEVEL_SETTLE_THEN_CUT
. While the new behavior should be safer, be aware that these commands will now cause locomotion before sitting and powering off.
The robot may not be commanded to go to the battery change pose when docked.
The Graph Nav map may not be cleared in the middle of recording.
The DataAcquisitionStore service is queryable for the IDs of items that have been stored by it. It would previously track everything that had been stored since the last time that the robot had been restarted. As of 3.1, it will track only the last 10,000 items stored.
The bosdyn-client
package no longer depends on requests
.
When a network transport failure occurs, depending on the particular operating system and version of gRPC installed, the error from the python SDK may not always be the most specific error possible, such as UnknownDnsNameError
. It may instead be raised as either a generic RpcError
, or another generic failure type such as UnableToConnectToRobotError
.
Spot CAM LED illumination levels are not currently recorded or played back in Autowalk missions.
If you write a custom data acquisition plugin or image service, do not change its DataAcquisitionCapability
or ImageSource
set once it is running and registered. New capabilities may not be detected, and old capabilities may still be listed as available in the Data Acquisition service. To change the capabilities of a service: unregister it from the directory, wait until its capabilities are no longer listed in the Data Acquisition service, and then re-register it. This waiting also applies to restarting a service if its capabilities will be different upon restart.
If you write a custom data acquisition plugin without using our helper class, its GetStatus()
RPC is expected to complete immediately. If it takes too long to complete it can cause timeouts when requesting GetStatus()
of the data acquisition service.
If you register a new service with the robot, calling robot.ensure_client()
to create a client for that service may result in a UnregisteredServiceNameError
.
- Workaround: call
robot.sync_with_directory()
beforerobot.ensure_client()
SE2VelocityLimits require care. Correct usage of the SE2VelocityLimit
message requires the user to fully fill out all the fields, setting unlimited values to a large number, say 1e6.
All examples have been changed to read the username and password from environment variables instead of taking --username
and --password
arguments.
Additionally, most examples now use the LeaseKeepAlive for complete lease management by setting the must_acquire
and return_at_exit
arguments to True
at construction. This helps ensure that the lease is properly returned when the example is complete.
The arm and manipulation examples have been updated to use the new block_until_arm_arrives()
helper instead of sleep()
calls.
The included Dockerfiles now contain default command line arguments for their entrypoints where appropriate. This means that it is not necessary to specify any command line arguments when running them in their default configuration (on the Spot CORE). However when running in a non-default configuration, all command line arguments will need to be specified.
Comms Mapping (new) Creates an image service that can be selected on the tablet controller that displays a map of wifi signal strength.
Gripper Camera Params (new) Demonstrates how to control the capture parameters for the gripper camera.
Ray Cast (new) Demonstrates how to perform ray-casting queries using the new RayCastService.
Animation Recorder (updated) First checks if the robot has the correct license for choreography.
Arm Force Control (updated)
Updated to use the new BodyAssistForManipulation
parameters.
Arm Gcode (updated)
Some updates to parsing gcode files. Added a new --test-file-parsing
option to only try to read the file, without executing it.
Arm joint move (updated) Added a more advanced example that shows how to send a continuous trajectory with many points.
BDDF download (updated) Fixed the ping check on Windows.
Data Acquisition (updated) Includes a new example plugin that saves battery data. This is used as part of the Data Collection Tutorial
Get Image (updated)
Supports a new --pixel-format
option to be able to specify the desired format.
Graph Nav Command Line (updated)
The recording example correctly handles the NotReadyYetError
response when stopping recording.
Ricoh Theta (updated) Includes support for pixel format and resize ratio.
Spot CAM (updated) Fixed a memory leak related to audio streams.
Tester Programs (updated) The image service tester only requests image and pixel formats that the service reports that it supports, and it will check that the returned type matches the requested type. It will also report a summary at the end of all errors and warnings it found.
Upload Choreographed Sequence (updated)
Checks that the robot is correctly licensed for choreography before running.
Includes a new --upload-only
option that will upload the sequence without running it.
Basic Streaming Visualizer (updated) Added an example to draw gripper depth data as a point cloud.
Web Cam Image Service (updated) Includes support for pixel format and resize ratio.
World Object Mutations (updated) Demonstrate using the new drawing helper.
Xbox Controller (updated) Cleaner lease usage throughout.
Reduced RPC calls to the Fault service in image_service_helpers.py
.
Example documentation cleanup and improvements.
Same as 3.0.0
Added GetSystemLog
RPC in SpotCAM Health service to retrieve an encrypted log of system events, for factory diagnosis of possible issues.
Fixed UploadEdgeSnapshot typo in GraphNav client.
Fixed usage of SE2Trajectory
robot commands in mission service.
Same as 3.0.0
Added COLORMAP_INFERNO
and COLORMAP_TURBO
as SpotCAM IR color map options.
The new base_tform_sensor
fields in SpotCAM protos have the transform in the right direction. The old base_tfrom_sensor
fields, now deprecated, had the inverse transform.
Deprecated field base_tfrom_sensor
in SpotCAM camera proto and added field base_tform_sensor
so it follows the intended naming convention.
Deprecated field base_tfrom_sensor
in SpotCAM logging proto and added field base_tform_sensor
so it follows the intended naming convention.
Deprecated the decode_token()
and log_token_time_remaining()
functions in bosdyn.client.sdk
. The SDK no longer supports decoding tokens. If you need to decode one, use pyjwt directly.
Same as 3.0.0
Arm Constrained Manipulation (updated) Cleanup to clamp normalized velocity and also use normalized velocity for knob.
GraphNav Command Line (updated) Improved handling in certain failure cases
Spot Cam (updated) Handle new IR color map options and removed the usage of the deprecated pose fields
Map Processing The new map processing service provides two ways to process the data in a graph nav map:
- adding new waypoints and edges to close loops and add connections in a map
- optimizing “anchorings” of a map, which will generate optimized positions of waypoints in the world for display or navigation.
Navigate to Anchor A new NavigateToAnchor RPC can be used to command GraphNav to drive the robot to a specific place in an anchoring. GraphNav will find the waypoint that has the shortest path length from the robot's current position but is still close to the goal.
See the Graph Nav documentation for more information.
Auto Return is a service which can be configured to take control of the robot in the event of a communication loss, and return it back along its recently traveled route to attempt to regain communications with its user. See the Auto Return documentation for more details.
The Choreography API now provides 'choreography logging' which will capture timestamped data about the robot's pose and joint state for either a user defined time period or for the duration of a dance. See the Choreography Service documentation for more details.
Users can now create animated moves using timestamped keyframes; these can be built through common animation software (like Autodesk Maya), handwritten, or constructed from choreography log data. The animated moves can be uploaded to the robot and used within dances like the base moves. See the Animations Overview documentation for more details.
The constrained manipulation API provides the functionality to manipulate objects such as cranks, levers, cabinets and other similar objects with Spot. The API allows for the selection of a task type along with the desired task velocity to manipulate the object.
API and tablet support for opening pushbar doors. The AutoPush API command takes a push point which the robot uses to detect the door and push it open at the specified location. See door.proto or arm_door.py for more details.
New SetPtzFocus and GetPtzFocus RPCs allow for control over the focus of the PTZ camera.
Payload registration now supports mounting payloads to the wrist or gripper of the arm. The new MountFrameName enum contains the valid mounting locations.
A new UpdatePayloadAttached RPC allows for attaching and detaching payloads while the robot is operating.
Missions have a new STATUS_STOPPED
state that can be triggered by the new StopMission
RPC. This state differs from a paused mission in that it means that the mission is no longer running and cannot be resumed.
New mission node types:
BosdynNavigateRoute
: Use GraphNav via NavigateRouteBosdynRecordEvent
: Record an API event in the data buffer.SpotCamLed
: Change the brightnesses of the LEDs on a SpotCam.SpotCamResetAutofocus
: Reset the autofocus on a SpotCam PTZ.StoreMetadata
: Attach metadata to some data stored by a DataAcquisition node.RetainLease
: Keep mission leases alive while the mission is running. This allows the mission to run a larger variety of missions without requiring the mission service’s client to keep the lease alive.RestartWhenPaused
: Restarts its child tree when a mission resumes, rather than resuming its child from the state it was in when it paused.
A new IREnableDisable
service and request have been added. This request allows clients to enable/disable the robot's IR light emitters in the body and hand sensors. This new service supports special situations where Spot's emitters may interfere with a custom attached payload. Disabling the IR emission will cause a SystemFault to be raised and have a negative effect on mobility since the robot's perception system is hindered.
For RPCs that can fail because the robot is impaired, the response message now includes a RobotImpairedState message providing details about the nature of the impairment.
NavigationFeedbackStatus now includes body_movement_status to make it simple to determine when the body has come to rest after completing navigation.
Directed exploration and alternate route finding can now be disabled using new fields in TravelParams.
RouteFollowingParams have been added to NavigateRouteRequest to specify the desired behavior in certain situations (not starting from the start of the route, resuming a route, and becoming blocked on a route).
New methods navigate_to_full()
and navigate_route_full()
has been added to the Graph Nav client which will return the full response instead of just the command id.
Additional statuses have been added to NavigateRouteResponse (STATUS_NO_PATH
and STATUS_NOT_LOCALIZED_TO_MAP
) to capture possible errors.
UploadGraph can fail with STATUS_INVALID_GRAPH
when the specified graph is invalid, for example containing missing waypoints referenced by edges.
DownloadWaypointSnapshotRequest has an additional option to not include point cloud data. The new has_remote_point_cloud_sensor field in WaypointSnapshot indicates that the point has point cloud data from a remote service.
Starting to record a new map can fail with the new status STATUS_TOO_FAR_FROM_EXISTING_MAP
.
The RPC for creating a new waypoint can now be provided a list of world objects to include in that waypoint’s snapshot.
For very large missions, a new RPC has been added to the mission service to stream the mission to the robot in chunks, rather than as a single message. The chunks should still deserialize to the same LoadMissionRequest message when assembled.
When a mission node fails to compile, the resulting FailedNode message has a new string that lists the protobuf type of the node implementation.
We have improved the feedback for ArmJointMoveCommand Requests to now include the status of the underlying trajectory planner and to return the planner’s solved trajectory, which is the trajectory the robot will execute.
The ManipulationFeedbackState contains extra enum values for additional placing states that the robot can be in during manipulation.
By default, the robot will assume all grasped items are not “carriable”. We have modified ApiGraspOverride to be able to override the carry state to one of CARRIABLE
, NOT_CARRIABLE
, or CARRIABLE_AND_STOWABLE
.
If holding an item, the stowing behavior is:
NOT_CARRIABLE
andCARRIABLE
- The arm will not stow, instead it will stopCARRIABLE_AND_STOWABLE
- The arm will stow while continuing to grasp the item
In addition, the communication loss behavior of the arm when it is holding an item is also modified:
NOT_CARRIABLE
- The arm will release the item and stowCARRIABLE
- The arm will not stow, instead entering stopCARRIABLE_AND_STOWABLE
- The arm will stow while continuing to grasp the item
The docking state includes additional “in-between” states, DOCK_STATUS_UNDOCKING
and LINK_STATUS_DETECTING
that indicate that a process is still ongoing.
Additional errors have been added to DockingCommandResponse for particular ways that docking can fail (STATUS_ERROR_GRIPPER_HOLDING_ITEM
, STATUS_ERROR_NOT_AVAILABLE
, STATUS_ERROR_SYSTEM
).
The feedback also has a new error status: STATUS_ERROR_NOT_AVAILABLE
.
See the protobuf documentation for more details.
The docking python client include a new docking_command_full()
call which returns the full response instead of only the command id. Additionally a new docking_command_feedback_full()
returns the full feedback instead of only the status.
Models can now have a list of labels associated with them.
When the image is requested to be rotated, the rotation angle will be returned in the response.
DataAcquisitionCapabilities can now also report the plugin service name of the service that will be performing that acquisition.
The DataAcquisitionClient has a new acquire_data_from_request()
that takes a full request proto, instead of building it internally.
The DataService client has been updated to have the correct service name.
Power commands can now report a STATUS_OVERRIDDEN
if the robot overrides the power command and disables motor power.
Power command responses and feedback will report system faults if a fault blocks the power command from succeeding.
LeaseUseResults have been added to messages for RobotCommand and ManipulationApi
New helpers safe_power_off_robot()
and safe_power_cycle_robot()
can completely power off the robot or power cycle the robot from any robot state.
Additional options have been added to ObstacleParams for tuning obstacle avoidance by turning off negative obstacle avoidance or body assist for avoiding foot obstacles.
Leases represent ownership over the robot. Leases have been updated to support ownership over only part of the robot, so that you can delegate control to different services, such as using Graph Nav to control robot mobility while simultaneously controlling the robot’s arm via a user-written script. Details are in the lease documentation, but in general users can just continue to use the “body” lease and everything will work as expected.
The image service will now report PixelFormat
for JPEG image sources even though the pixel format can be determined from the JPEG header.
Spot Check has some additional failure statuses that it can report.
Events logged to the data buffer may now include a LogPreserveHint to tell the robot whether this event is worth preserving a log for.
RobotState now includes additional data about the terrain under each foot.
Additional properties have been added to world objects to assist in image processing.
An additional level of hierarchy has been added for transport-level errors to simplify most error cases. RpcError has two new subclasses: PersistentRpcError
and RetryableRpcError
. PersistentRpcError
indicates an error such that attempting to retry the call will fail again. RetryableRpcError
means that the call may succeed if retried.
Calling ensure_secure_channel()
directly will now result in max message sizes not being correctly.
Invalid RobotCommands will no longer result in STATUS_INVALID_REQUEST
in the RobotCommandResponse message, but will instead use the CODE_INVALID_REQUEST
error in the common header, like other RPCs do. In the python client library, this will still raise the same InvalidRequestError
as before.
E-stops may not be unregistered from the estop service while the robot’s motors are powered. This prevents accidentally powering the robot off. A new STATUS_MOTORS_ON
status will be returned in the response to indicate this error. To unregister an estop, first safely power off the robot.
RPCs to the AuthService and PayloadRegistration service are now rate-limited to 5 and 10 requests/second respectively. Requesting more than that will result in an HTTP 429 error, or raising the TooManyRequestsError
if using the python client.
The “obstacle_distance” local grid inadvertently included some generated obstacles used only for foot-placement control. These grids no longer include those generated obstacle regions.
The python function bosdyn.client.lease.test_active_lease
previously took an optional make_sublease
argument. That has been replaced with an optional sublease_name
argument so that if a sublease is desired, it gets created with a client name correctly.
The StraightStaircase message has been moved to bosdyn/api/stairs.proto so that it can be used in more places. This is compatible with existing serialized protobufs, but any code that is manually creating these messages will need to be updated.
The enable_grated_floor
field is superseded by the new grated_surfaces_mode
which will auto-detect the need for grated surface handling.
The safe_power_off()
helper has been replaced by the less ambiguous safe_power_off_motors()
helper.
The docking_command_feedback()
method of DockingClient incorrectly raised an exception if the docking command had encountered lease errors, and has been replaced by docking_command_feedback_full()
which returns the full feedback response.
For limiting the speed on an edge, use the vel_limit
in mobility_params
instead of the Edge annotation’s vel_limit
.
Docking nodes should not use the child node anymore. If a mission needs to react to docking results, it should use the responses written into the blackboard by the docking node.
The guid
and secret
fields on payload registration RPCs have been replaced with a standardized PayloadCredentials
message.
Many helpers for writing services and filling out responses have been moved from bosdyn.client.util
to bosdyn.client.server_util
.
bosdyn.mission.server_util.set_response_header()
has been moved to bosdyn.client.server_util.set_response_header()
, so that it can be used by any service, not only those depending on missions.
When a network transport failure occurs, depending on the particular operating system and version of gRPC installed, the error from the python SDK may not always be the most specific error possible, such as UnknownDnsNameError
. It may instead be raised as either a generic RpcError
, or another generic failure type such as UnableToConnectToRobotError
.
Spot CAM LED illumination levels are not currently recorded or played back in Autowalk missions.
If you write a custom data acquisition plugin or image service, do not change its DataAcquisitionCapability
or ImageSource
set once it is running and registered. New capabilities may not be detected, and old capabilities may still be listed as available in the Data Acquisition service. To change the capabilities of a service: unregister it from the directory, wait until its capabilities are no longer listed in the Data Acquisition service, and then re-register it. This waiting also applies to restarting a service if its capabilities will be different upon restart.
If you write a custom data acquisition plugin without using our helper class, its GetStatus()
RPC is expected to complete immediately. If it takes too long to complete it can cause timeouts when requesting GetStatus()
of the data acquisition service.
If you register a new service with the robot, calling robot.ensure_client()
to create a client for that service may result in a UnregisteredServiceNameError
.
- Workaround: call
robot.sync_with_directory()
beforerobot.ensure_client()
SE2VelocityLimits require care. Correct usage of the SE2VelocityLimit
message requires the user to fully fill out all the fields, setting unlimited values to a large number, say 1e6.
Animation Recorder (new) Demonstrates recording motion made with the tablet and then playing it back with the choreographer service.
Arm Constrained Manipulation (new) Demonstrates using constrained manipulation to turn a crank.
Auto Return (new) Demonstrates setting up and triggering the Auto Return service.
Data Buffer (new) Demonstrates adding several different kinds of data to the data buffer.
Get Depth Plus Visual Image (new)
Demonstrates how to use the depth_in_visual_frame
image sources to visualize depth in a visual image.
Graph Nav Extract Point Cloud (new) Demonstrates opening and parsing a GraphNav map and extracting a globally consistent point cloud from it.
Post-Docking Callbacks (new) Builds docker images for mission callbacks that can upload data acquired during a mission.
Disable IR Emission (new) Demonstrates enabling and disabling IR light emitters via the IREnableDisableService Client.
Arm Gaze (updated)
Updated to use block_until_arm_arrives()
instead of a sleep()
BDDF Download (updated) Now provides a Qt-based downloading UI.
Data Acquisition Service (updated) Now provides a plugin for capturing data from the network compute bridge.
Frame Trajectory Command (updated) Now takes arguments that specify how to move instead of performing fixed motions.
Graph Nav Command Line (updated) Now can navigate to a position in an anchoring. The recording example provides options to automatically close loops in the map or optimize the map's anchoring.
View Map (updated) Now can display the map according to the anchoring.
Mission Recorder (updated) New option to build a mission from the graph on the robot. New command to automatically close loops in the graph. Uses NavigateRoute to follow waypoints in order.
Network Compute Bridge (updated) Now includes options to run and test a worker without needing a robot. Also includes files to build docker images for deployment.
Payloads (updated) Now includes an example of how to attach and detach a payload.
Replay Mission (updated) Now includes extra options for playing back Autowalk missions, as well as disabling directed exploration.
Ricoh Theta (updated) Now includes a "live stream" option that provides a higher frame rate at the cost of lower-quality stitching. (Thanks Aaron Gokasian!)
Spot Cam (updated) New options for getting and setting PTZ focus, audio capture channel, and audio capture gain. Also an option for enabling congestion control for the stream quality.
WASD (updated) The Escape key can now be used to stop the robot.
Webcam Image Service (updated) New resolution options allow for capturing from the webcam at different resolutions.
Added InitializeLens
RPC, which resets the PTZ autofocus without needing to power cycle the Spot CAM.
A new sync
option has been added to RecordDataBlobsRequest
which specifies that the RPC should not return a response until the data has been fully committed and can be read back.
This is exposed through the optional write_sync
argument to the add_blob()
and add_protobuf()
methods of the DataBufferClient
.
When running with a Spot CAM+ (PTZ) running 2.3.5, the SetPowerStatus
and CyclePower
endpoints will now return an error if the PTZ is specified. These endpoints could previously cause the WebRTC feed to crash. These RPCs are still safe to use for other devices, but due to hardware limitations, resetting the PTZ power can possibly cause the Spot CAM to require a reboot to regain the WebRTC stream.
RetryableUnavailableError
was raised in more cases than it should have been, and it is now more selectively raised.
The EstopKeepAlive
expected users to monitor its status by popping entries out of its status_queue
. If the user did not do so, the queue would continue to grow without bound.
The queue size is now bounded and old unchecked entries will be thrown away. The queue size is specified with the max_status_queue_size
argument to the constructor.
As stated above, the behavior of SetPowerStatus
and CyclePower
endpoints have been changed for Spot CAM+ units when attempting to change the power status of the PTZ. They now return an error instead of modifying the power status of the PTZ. They remain functional for the Spot CAM+IR. Clients using these SDK endpoints to reset the autofocus on the PTZ are recommended to use InitializeLens
instead. Other clients are encouraged to seek alternative options.
The ResponseContext
helper class has been moved to the bosdyn-client package (from the bosdyn-mission package), so that it can be used for gRPC logging in data acquisition plugin services in addition to the mission service. The new import location will be from bosdyn.client.server_util
, and the original import location of bosdyn.mission.server_util
has been deprecated.
Same as 2.3.0
New options have been added to the Power Service to allow for power cycling the robot and powering the payload ports or wifi radios on or off. Additional fields have been added to the robot state message to check the payload and wifi power states. Support has also been added to the bosdyn.client
command line interface for these commands.
These new options will only work on some Enterprise Spot robots. Check the HardwareConfiguration message reported by a particular robot to see if it supports them.
Fixed an issue that could cause payload registration or directory registration keep-alive threads to exit early in certain cases.
Fixed a couple issues with the webcam example: updated the Dockerfile to create a smaller container specifically with python 3.7, added new optional argument to specify the video codec, and programmatically prevent substring arguments other than the --device-name
argument to avoid accidental confusion with the docker container's --device
argument.
Same as 2.3.0
A new tutorial has been added to walk through using machine learning, the Network Compute Bridge, and Manipulation API to play fetch with Spot.
The python Graph Nav client now allows setting an offset to the destination, for navigating to a position relative to the final waypoint instead of exactly matching the final waypoint position and orientation.
Fixed issues where the data acquisition download helpers did not handle absolute paths on windows and did not clean filenames correctly. (Thanks David from Levatas!)
Zip file names from the data download service no longer contain difficult characters.
Fixed an issue where Graph Nav would sometimes report the robot was impaired on the first usage after restarting the robot.
Errors returned from Network Compute Bridge workers will be better propagated in the Network Compute Bridge response.
Updated background threads for the payload and directory registration helpers to silently ignore transient errors.
Fixed an issue where requesting thermal images with PTZ/Pano images in a single data acquisition action caused thermal images to either not be collected or saved as “blank” images.
The estop service will now refuse to change configuration if the robot is already powered on, returning a status of STATUS_MOTORS_ON. This prevents accidentally cutting power while the robot is in operation.
Same as 2.3.0
Network Compute Bridge Updated to provide appropriate error messages from the workers.
The SpotCAM API has been expanded to support more use cases for the SpotCAM+IR (thermal PTZ variant). This includes the following new endpoints:
SetIrColormap
/GetIrColormap
: Set/get the mapping between radiometric IR samples to color, for videoSetIrMeterOverlay
: Set location for the "Spot Meter", which indicates temperature at a point in the thermal video stream.
The SpotCAM Power API now has an additional endpoint to cycle power for any of the components that could previously be toggled using SetPowerStatus
. CyclePower
can be used to help the PTZ recover from adverse behavior, such as incorrect auto-focus or poor motor behavior, which can sometimes happen as the result of a robot fall. CyclePower
will wait the appropriate amount of time between turning components off and turning on again to make sure the power is cycled correctly without the client needing to know the correct interval.
Same as 2.3.0
Get image (updated) Support for the new pixel format of IR images.
Ricoh Theta (updated)
Improved parsing of timestamp information from the camera.
Correctly set the image proto format field.
Defaults to not capturing continuously. Flags --capture-continuously
and --capture-when-requested
can be used to specify the desired behavior.
Spot CAM (updated) Support for IR images and power cycling functionality.
One of the main features of the 2.3 release is control and support of Spot's arm and gripper. Arm and gripper commands are included in the SynchronizedCommand
message, and can be commanded in addition to mobility commands. The RobotCommandBuilder
in the SDK provides many new helpers for building new arm and gripper commands. The synchro command builder functions now have an optional build_on_command
argument, which is used to build a mobility/arm/gripper command onto an existing command, merging them correctly.
The arm and gripper state are reported in the new manipulator_state
field of the robot state. The Python SDK Robot
class now has a has_arm()
helper to determine if the robot has an arm or not.
For more information about controlling the arm, see the arm documentation.
Manipulation API (beta) This new API provides some high-level control options for walking to and picking up objects in the world.
Arm Surface Contact (beta) ArmSurfaceContactService lets you accurately move the robot's arm in the world while having some ability to perform force control. This mode is useful for drawing, wiping, and other similar behaviors.
Doors (beta) DoorService will automatically open and move through doors, once provided some information about handles and hinges.
An interface for integrating real-time image processing and machine learning for identifying objects and aiding grasping. For more information, see the network compute bridge documentation.
A new PayloadEstimationCommand
is available to have Spot try to estimate the mass properties of a payload itself. After moving about to perform its estimation, the mass properties will be reported in the command feedback.
Some SpotCAMs now include an IR camera. There are additional cameras and screens available for those versions, and a new pixel format PIXEL_FORMAT_GREYSCALE_U16
used to represent those IR images. There are additional RPCs used to set colormaps and overlays of the IR images for live display.
Logpoint QUEUED
status is now broken up further with the queue_status
field, which differentiates between when the image has or has not been captured.
The new Choreographer executable now includes two new tracks, gripper and arm, and includes new dance moves which control the arm.
A new PREP_POSE_UNDOCK
command option can be used to undock a docked robot. It will return the new STATUS_ERROR_NOT_DOCKED
if the robot was not already docked. When successful the status will be STATUS_AT_PREP_POSE
.
When localizing the robot using FIDUCIAL_INIT_SPECIFIC
, if the target waypoint does not contain a good measurement of the desired fiducial, nearby waypoints may be used to infer the robot's location. This behavior can be disabled with the new restrict_fiducial_detections_to_target_waypoint
field to only use the waypoint’s own data.
A new destination_waypoint_tform_body_goal
is provided for the NavigateTo
and NavigateRoute
RPCs. This allows the user to specify a goal position that is offset from the destination waypoint, rather than exactly on the waypoint.
A new command_id
field can be specified on the NavigateTo
and NavigateRoute
RPCs. This is used to continue a previous command without needing to re-specify all the data. An important difference between specifying the command_id
versus sending a new command is that if the robot has reported itself stuck, continuing a command will result in a STATUS_STUCK
error, rather than trying again. A new STATUS_UNRECOGNIZED_COMMAND
will be returned if the command_id
does not match the currently executing command.
The map representation now tracks the “source” of waypoints and edges. It is possible to override the cost of an edge used when planning paths and to disable the alternate route finding for a particular edge.
Leases now include client names alongside the sequence number for help in debugging. If you are writing a custom client, make sure to append your client name any time that you create a sub-lease.
ListLeases can optionally request to have the full lease information of the latest lease, rather than only the root lease information that was previously reported.
In the seconds following modifications to the robot directory to the robot directories existing clients may experience a one time request failure. This failure is transient and can be resolved by retrying the request. This has been an expected failure case and a new error (RetryableUnavailableError) has been put in to better reflect the failure.
SE3Pose
and Quat
math helpers have transform_vec3
members to simplify rotating vectors.
There is a new get_self_ip()
helper in common.py
for determining the ip address your client will use to talk to the robot. This is useful for determining the correct registration information for a service, particularly on a machine with multiple network interfaces. This is also available via the python command line program python3 -m bosdyn.client <robot host> self-ip
.
When listing events from the python command line program, you can now filter by event level and by event type.
The python SDK now depends on the Deprecated
package, which is used to mark functions and classes that are deprecated and provide warnings, so that users are made aware that features that they are using may be removed in the future.
The Deprecated package has been implemented across the SDK so that deprecated features will print out a warning when they are called. Documentation surrounding deprecated features has also been updated.
Spot Check no longer computes the foot_height_results
or leg_pair_results
fields.
All RPCs in the Python SDK have a default timeout of 30s. The global timeout can be changed by assigning a new value to bosdyn.client.common.DEFAULT_RPC_TIMEOUT
, and individual RPC calls can still set their own timeout via a timeout=sec
optional parameter at any call site.
When a network transport failure occurs, depending on the particular operating system and version of gRPC installed, the error from the python SDK may not always be the most specific error possible, such as UnknownDnsNameError
. It may instead be raised as either a generic RpcError
, or another generic failure type such as UnableToConnectToRobotError
.
Spot CAM LED illumination levels are not currently recorded or played back in Autowalk missions.
When capturing both a PTZ and Panoramic image in the same action, there may occasionally be two PTZ images captured along with the Panoramic image, rather than just one.
If you write a custom data acquisition plugin or image service, do not change its DataAcquisitionCapability
or ImageSource
set once it is running and registered. New capabilities may not be detected, and old capabilities may still be listed as available in the Data Acquisition service. To change the capabilities of a service: unregister it from the directory, wait until its capabilities are no longer listed in the Data Acquisition service, and then re-register it. This waiting also applies to restarting a service if its capabilities will be different upon restart.
If you write a custom data acquisition plugin without using our helper class, its GetStatus()
RPC is expected to complete immediately. If it takes too long to complete it can cause timeouts when requesting GetStatus()
of the data acquisition service.
If you register a new service with the robot, calling robot.ensure_client()
to create a client for that service may result in a UnregisteredServiceNameError
.
- Workaround: call
robot.sync_with_directory()
beforerobot.ensure_client()
SE2VelocityLimits require care. Correct usage of the SE2VelocityLimit
message requires the user to fully fill out all the fields, setting unlimited values to a large number, say 1e6.
Arm and Mobility Command (new) Demonstrates how to issue both mobility and arm commands to the robot at the same time.
Arm Door (new) Demonstrates how to use the door service to have Spot autonomously open a door. It opens an image display and requires the same use input as when opening a door with the tablet.
Arm Force Control (new) Demonstrates how to create force controlled trajectories for the arm and gripper.
Arm Gaze (new) Shows how to command multiple different types of gaze requests.
Arm GCode (new) Uses the arm surface contact API to write GCode on the ground using sidewalk chalk.
Arm Grasp (new) Shows how to use the manipulation API to autonomously grasp an object based on the object’s image coordinates in pixel space. It opens an image view and lets a user select an object by clicking on the image, similar to grasping with the tablet.
Arm Joint Move (new) Shows how to create and command a joint move trajectory.
Arm Simple (new) A starter example which shows how to issue the robot command RPC with a basic arm command which moves the end effector to a couple different positions.
Arm Stow Unstow (new) Shows how to issue API commands to stow and unstow the arm.
Arm Surface Contact (new) Uses the arm surface contact API to request an end effector trajectory move which applies some force to the ground.
Arm Trajectory (new) Demonstrates how to create an arm command with a position-based trajectory.
Arm Walk to Object (new) This example shows how to use the manipulation api to command the robot to walk towards an object and prepare to grasp it. The example opens an image view and lets a user select an object by clicking in the image.
Arm With Body Follow (new) Shows how to issue arm commands that allow the body to move to a good position to achieve the desired arm command.
Comms Test (updated) The comms test example can now successfully be run with Docker.
Data Acquisition Service Plugins (updated) The directory structure has changed to create individual directories for each plugin (and the plugin’s Dockerfile and requirements files).
Data Service (updated) A new example script, delete_pages.py, has been added to remove log pages from robots.
Estop (updated) The estop no-gui example’s logging statements have been improved.
GraphNav Command Line (updated) Has commands to clear the map on the robot, and to manually close the loop in a map. Updated to properly return the lease when exiting the script. Optimized to only upload snapshots to the robot that are not already present.
Mission Recorder (updated) Fixed the localization node to use the nearest fiducial.
Network Compute Bridge (new) The example has a network compute bridge work service example, which runs a tensorflow model and registers the service with the robot. Additionally, the example contains a client-side example that queries the network compute bridge service to identify objects in the robot camera images using the server’s tensorflow model.
Replay Mission (updated) Optimized to only upload snapshots to the robot that are not already present. Has an option to disable alternate route finding when running a mission.
Ricoh Theta (updated) Fixes a missing import required to run the continuous capture thread.
Self Registration (updated) Updated to create a payload with more realistic sample values.
Spot CAM (updated) The WebRTC example now records audio. The compositor example now includes Spot CAM IR support.
Upload Choreographed Sequence (updated) Returns a clearer error message if being used with an incorrect license.
Web Cam Image Service (updated) The web cam example now has better support for Windows, and has a debug mode which will show a popup image window of the camera image.
Automated docking at charging stations is out of beta and available for enterprise customers. There have been a few updates to the protos regarding status reporting and handling "prep" poses.
Payloads that have been registered with the robot but have not yet been authorized will automatically have service faults raised on their behalf indicating their status. This will help prevent operators from forgetting to authorize payloads after attaching them to the robot.
Image Services Helper functions for creating image services that reduce the amount of boiler plate code required for creating an image service and ensure the necessary fields of the response RPCs will be populated by the service.
Data Acquisition Service
Helper functions for communicating with the on robot data acquisition service to acquire data, monitor the status of the acquisition, cancel requests, and download the data using the REST endpoint. These functions originally were in the data_acquisition_service example, but are now part of the bosdyn-client
wheel.
Added new status STATUS_NEAR_GOAL
as well as a new BodyMovementStatus
to help differentiate between different kinds of states the robot can be in at the end of its trajectory.
The BosdynGraphNavLocalize
node can now specify a full SetLocalizationRequest
, rather than only localizing to the nearest fiducial.
When comparing blackboard values, there is a new HandleStaleness
option to specify what the node should do if the blackboard value is stale.
is_estopped()
helper for the estop client and robot.- Helper functions to create time ranges in the robot’s time.
- Downloader script for bddf log files.
Data Acquisition Data Acquisition Service on robots is now robust to port number changes. The previous workaround to this problem was to always specify the same port when starting/restarting a service. Now, the port argument for external api services can use the default, which will choose an available ephemeral port.
Image Services
Robot Cameras image service will respond to GetImage requests with incorrect format (e.g. requesting a depth image as format JPEG) using the STATUS_UNSUPPORTED_IMAGE_FORMAT_REQUESTED
. Previously, this was returned as STATUS_IMAGE_DATA_ERROR
.
The Ricoh Theta image service example improvements
- Automatically disables sleep mode when putting the ricoh theta into client mode (using
ricoh_client_mode.py
). - By default, it now runs a background thread capturing images continuously to minimize the delays waiting for an image to appear when viewing from the camera.
- It will wait for the capture to be completely processed before returning an image. This fixes issues where a very old image would be displayed, since it would trigger a take picture, but just return the most recent processed image.
Command line client The "log" and "textmsg" commands now go through the DataBuffer service, and so can be read back by downloading bddf files from the robot.
EstopService timeout The maximum timeout on the EstopService (aka the motor cut authority) has been raised from 65 seconds to just over 18 hours and 10 minutes. The estop service also correctly reports an error if given an invalid timeout.
BDDF code has moved to the bosdyn-core
package, so that it can be used separately from the client code. The new import location is bosdyn.bddf
. The old import path via bosdyn.client.bddf
is deprecated.
bosdyn-client
now depends on the requests
library for making http requests to download data acquisition results and bddf logs.
When a network transport failure occurs, depending on the particular operating system and version of gRPC installed, the error from the python SDK may not always be the most specific error possible, such as UnknownDnsNameError
. It may instead be raised as either a generic RpcError
, or another generic failure type such as UnableToConnectToRobotError
.
Spot CAM LED illumination levels are not currently recorded or played back in Autowalk missions.
When capturing both a PTZ and Panoramic image in the same action, there may occasionally be two PTZ images captured along with the Panoramic image, rather than just one.
If you write a custom data acquisition plugin or image service, do not change its DataAcquisitionCapability
or ImageSource
set once it is running and registered. New capabilities may not be detected, and old capabilities may still be listed as available in the Data Acquisition service. To change the capabilities of a service: unregister it from the directory, wait until its capabilities are no longer listed in the Data Acquisition service, and then re-register it. This waiting also applies to restarting a service if its capabilities will be different upon restart.
If you write a custom data acquisition plugin without using our helper class, its GetStatus()
RPC is expected to complete immediately. If it takes too long to complete it can cause timeouts when requesting GetStatus()
of the data acquisition service.
If you register a new service with the robot, calling robot.ensure_client()
to create a client for that service may result in a UnregisteredServiceNameError
.
- Workaround: call
robot.sync_with_directory()
beforerobot.ensure_client()
SE2VelocityLimits require care. Correct usage of the SE2VelocityLimit
message requires the user to fully fill out all the fields, setting unlimited values to a large number, say 1e6.
Image service test program (new) A new tester program for image services is available to help with the development and debugging of new image service implementations.
Docking (new) Shows how to trigger the docking service to safely dock the robot on a charger.
Web Cam Image Service (updated) The web cam example now uses the new image service helpers.
Ricoh Theta Image Service (updated) Uses the new image service helpers. A few extra bug fixes as described above.
Data Service (updated) Added options to specify a time range, and automatically converts times to robot time.
Data acquisition (updated)
Uses the new data acquisition helpers. The data acquisition tester program has been moved to a common tester_programs
directory.
Spot I/O: Data Acquisition
This release features a new system for acquiring, storing, and retrieving sensor data. It consists of several new services and their associated clients.
Data Acquisition Service: The coordinating service that will capture images, robot metadata, and delegate to plugins to capture custom sensor data.
Data Acquisition Plugins: User-implemented services that can capture data from sensors and save it into the store.
Data Acquisition Store: Interface for saving data and metadata to disk for later retrieval.
Image services: Existing interface used in a new way. User-implemented image services will now be displayed in the tablet for driving, and be automatically capturable by the Data Acquisition Service.
Stance: Allows precise placement of the feet of the robot, beyond just positioning the body.
Battery change pose: Rolls Spot over so that the battery is accessible removal and replacement.
Several changes have been made in preparation for the release of Spot’s arm. These represent new ways to accomplish the same control as before, but in a way that will be compatible with also controlling the robot’s arm in a future release.
Synchronized commands and feedback: A new synchronized_command for combining mobility control with arm and gripper control. This deprecates the mobility_command
in the RobotCommand
message. Additionally, the top-level command status has been moved into the individual full-body and mobility command feedback messages so that mobility and arm commands can individually report their state.
Stop: The existing full-body Stop
command still exists, but there is an additional mobility-only Stop
command that can be used to only stop the mobility without affecting any separate arm control.
To simplify the development of reliable services and report when problems arise, a new set of reportable faults has been added, usable by all services.
Fault Service: Used to report or clear faults pertaining to a service or payload. The Python SDK includes a client library for triggering and clearing faults through this service.
ServiceFaultState in RobotState: All reported service faults will be included in the RobotState
message. Clearing active faults will move them into historical faults. All service faults will automatically be displayed in the tablet interface to inform users.
Directory and Payload Liveness faults: New options for directory and payload registration enable liveness monitoring. When this feature is implemented, alongside directory or payload keep-alives, service faults will be automatically raised when a service crashes or a payload disconnects.
Integrations: Boston Dynamics supported payloads incorporate service faults and liveness monitoring out of the box.
- Spot CORE will report service faults if it experiences issues during startup, fails to communicate with the robot, detects an invalid payload configuration, or fails to communicate to an expected LiDAR.
- Spot CAM will report service faults if it is disconnected from Spot or if any of its internal services crash.
- The
bosdyn.client
command line interface can show and monitor reported faults.
The robot now dedicates some internal storage space to user data and logging. In addition to the data acquisition system, the user can store messages, events, time-series data, or arbitrary binary blobs.
Data Buffer: New service interface for storing various kinds of data on the robot.
Data Service: Retrieval service that can be used to return the data stored in the data buffer.
BDDF: File format for large downloads of stored data, and tools for reading the file.
Download endpoints: HTTPS download of a zip file of data acquisition mission datasets or bddf-encoded data.
Point cloud service definitions are provided for retrieving point cloud data from LiDAR sensors, such as from the EAP payload.
Congestion control is now available for WebRTC streaming. External microphones supported, with control for selecting microphones and setting gain levels individually. Note: External microphone support only available on Spot CAM + IR.
The localization data now includes a transform to a "seed" frame, providing a consistent global frame for use across multiple runs on the same map.
Localization data can be requested relative to a particular waypoint, rather than only the waypoint that the robot is currently localized to.
Additional control for determining whether the robot will navigate through areas with poor quality features.
Additional mission nodes which support new functionality:
- Point the Spot CAM PTZ to a specified orientation.
- Dock the robot at a charging station.
- Capture data through the data acquisition service.
- Manipulate strings in the blackboard.
Play advanced choreographed routines for Spot. The choreography service requires a special license to use.
The new docking service provides a way to autonomously dock at a charging station. It is currently in beta, and requires a special license to use.
Graph Nav
- Added fiducial-related status errors in
SetLocalizationResponse
, such as a fiducial being too far away or having poor data. - Edges now record mobility params that were set during record time, and use them when navigating those edges.
- “Stuck” detection has changed, and the robot will report much sooner when it has no way to make progress.
- Improved
StartRecordingResponse
andCreateWaypointResponse
to report errors about bad fiducials or point cloud data.
Fiducial Detection
- Fiducials now report a filtered pose in addition to the raw detected pose, to avoid jitter in individual detections.
- Fiducial detections include extra information, such as the detection covariance, camera frame, and status regarding ambiguity or error.
Mission Nodes
- The
BosdynGraphNavState
node can specify the id of the waypoint to use for the reported localization.
Spot Check
- Added status field in
SpotCheckCommandResponse
. - Improved the list of errors in
SpotCheckFeedbackResponse
message. - Spot Check now checks and reports results on hip range of motion.
Python client
- Blocking “power on” and “power off” helpers report errors correctly, rather than always raising
CommandTimedOutError
if the robot could not power on or off. - Added helper classes for registering and launching services.
- Added the ability to authenticate the robot instance from payload credentials.
- Printing the Spot SDK exceptions now provides more information.
- Increased default message size limit for receiving and sending messages to 100 MB
- Command line interface supports the new 2.1 functionality
- Payload commands.
- Payload registration commands.
- Fault commands.
- Data buffer commands.
- Data service commands.
- Data acquisition commands.
Image capture parameters
- Added exposure and gain parameters associated with an image capture.
License interface
- Added
GetFeatureEnabled()
to theLicenseService
to query for particular license features.
Robot Control
A behavior fault (CAUSE_LEASE_TIMEOUT
) is raised when the usage of a lease times out, and must be cleared before the robot can be commanded again. This should have minimal effect on current clients, as this happens near the same time that the robot powers off from comms loss (which clears behavior faults).
Graph Nav
When GraphNav reports STATUS_STUCK
while navigating, the robot will stop walking. It will need to be re-commanded to navigate in order to continue. Previous behavior was that the robot would continue walking when stuck until commanded to stop by a client.
Missions
Autowalk mission callback nodes only wait 10 seconds for a response. When a mission calls Tick()
on a mission callback service, it expects a quick response. In 2.0 it would wait up to 60 seconds for a response before retrying. This has been reduced to 10 seconds in version 2.1. Callbacks that do any significant work should be written to return with STATUS_RUNNING
quickly, and then continue to do their work on another thread rather than trying to fit in all of their work before returning a response. The service can then base their response to subsequent Tick()
requests on the status of that thread.
When a network transport failure occurs, depending on the particular operating system and version of gRPC installed, the error from the python SDK may not always be the most specific error possible, such as UnknownDnsNameError
. It may instead be raised as either a generic RpcError
, or another generic failure type such as UnableToConnectToRobotError
.
Spot CAM LED illumination levels are not currently recorded or played back in Autowalk missions.
When capturing both a PTZ and Panoramic image in the same action, there may occasionally be two PTZ images captured along with the Panoramic image, rather than just one.
If you write a custom data acquisition plugin or image service, do not change its DataAcquisitionCapability
or ImageSource
set once it is running and registered. New capabilities may not be detected, and old capabilities may still be listed as available in the Data Acquisition service. To change the capabilities of a service: unregister it from the directory, wait until its capabilities are no longer listed in the Data Acquisition service, and then re-register it. This waiting also applies to restarting a service if its capabilities will be different upon restart.
Furthermore, always specify the port that it should run on via the --port
flag, and do not change it between restarts of your plugin or image service. If you must change the port, then you must reboot the robot.
If you write a custom data acquisition plugin without using our helper class, its GetStatus()
RPC is expected to complete immediately. If it takes too long to complete it can cause timeouts when requesting GetStatus()
of the data acquisition service.
If you configure the estop service with custom timeouts and set an invalid timeout, you will not receive an error, but the robot will set the timeout to something else. The maximum estop timeout is 60 seconds, and the maximum estop cut_power_timeout is 65 seconds.
If you register a new service with the robot, calling robot.ensure_client()
to create a client for that service may result in a UnregisteredServiceNameError
.
- Workaround: call
robot.sync_with_directory()
beforerobot.ensure_client()
SE2VelocityLimits require care. Correct usage of the SE2VelocityLimit
message requires the user to fully fill out all the fields, setting unlimited values to a large number, say 1e6.
The following services, fields, and functions will continue to work, but will be removed in a future version.
The LogAnnotationService
is replaced with the DataBufferService
, which allows user access to the logged data.
Mobility commands have been moved from RobotCommand
, and into SynchronizedCommand
within RobotCommand
. When changing clients to use SynchronizedCommand
, be aware that the feedback will be in the new SynchronizedCommand
feedback. The top-level command status is also deprecated in favor of a status within individual feedback messages. Changing clients to use the new SynchronizedCommand
will make them compatible with arm commands in a future release.
The representation of SE3Covariance
has changed to a matrix. The individual element representation is deprecated.
In the map edge annotations, the ground_mu_hint
and grated_floor
fields have moved into the mobility_params
message.
The helper functions in RobotCommandBuilder
have new versions that use the new SynchronizedCommand
.
sit_command()
→ synchro_sit_command()
stand_command()
→ synchro_stand_command()
velocity_command()
→ synchro_velocity_command()
trajectory_command()
→ synchro_se2_trajectory_point_command()
The non-synchro versions are deprecated, and will be removed at the time that the mobility commands are removed from RobotCommand
.
- Example data acquisition plugin implementations.
- Examples for capturing and downloading data.
- Test program to validate a data acquisition plugin.
Comms Test (new) Demonstrates how to use the SDK to perform comms testing.
Data Service (new) Get comments and data index information from the robot.
Ricoh theta image service (new)
Create a standard Boston Dynamics API ImageService
that communicates with the Ricoh Theta camera.
Service faults (new) Demonstrates raising service faults, clearing service faults, and implementation of directory liveness checks.
Spot detect and follow (new) Collects images from the two front Spot cameras and performs object detection on a specified class.
Stance (new) Exercises the stance function to reposition the robots feet.
Stitch front images Demonstrate how to stitch the front camera images together into a single image in an OpenGL shader.
Upload choreographed sequence (new) Shows how to use the Choreography service to upload an existing choreographed sequence to the robot, and have the robot execute that uploaded routine.
Velodyne client (new) Demonstrates how to use the Velodyne service to query for point clouds.
Web cam image service (new)
Implements the standard Boston Dynamics API ImageService
and communicates to common web cameras using OpenCV.
World object with image coords (new) Demonstrates adding a world object that exists only in image coordinates, rather than having a full transform.
- Uses the new
SynchronizedCommand
for robot commands.
Frame trajectory command (updated)
- Uses the new
SynchronizedCommand
for robot commands.
- Added an option to auto-rotate images to be rightside-up.
- Added an option to retrieve images from user image services.
- Added support for more pixel formats.
GraphNav command-line (updated)
- Waypoints can be specified by either short codes or waypoint names.
- Waypoints sorted by creation time.
- Uses the new
SynchronizedCommand
for robot commands.
- Switched to use Data Buffer for logging instead of the deprecated
LogAnnotationService
.
Mission question answerer (updated)
- Updated to prompt the user on the command line for an answer.
- Added support for navigating through feature-poor areas.
- Uses the new payload keep-alive.
Remote mission service (updated)
- Separated example_servicers.py into separate hello_world_mission_service.py and power_off_mission_service.py files.
- Added an option to skip the initial localization.
- Uses new helpers for registration.
- New option to delete all images from the USB drive.
- Support for the IR camera.
- Uses the new
SynchronizedCommand
for robot commands.
- Uses the new
SynchronizedCommand
for robot commands. - Supports battery change pose command.
- Uses the new
SynchronizedCommand
for robot commands. - Supports battery change pose command.
Ricoh Theta remote mission service (removed)
- This has been removed and replaced with the Ricoh Theta image service, which provides better integration for displaying and capturing data.
get_depth_plus_visual_image (removed)
- Example removed because all robot cameras include
depth_in_visual_frame
sources by default.
Spot check (removed)
- Users can run Spot Check from the tablet.
- Power Client detects errors during a power command right away and propagates them up to the application before the command timeout is reached.
Release 2.0.2 contains the same issues as release 2.0.1, listed below.
If you delete an object from the world object service, there is a chance that a ListWorldObjects call immediately afterward may still include that object.
- Workaround: wait a short time before expecting the object to be gone.
If you register a new service with the robot, calling robot.ensure_client to create a client for that service may result in a UnregisteredServiceNameError.
- Workaround: call robot.sync_with_directory() before robot.ensure_client()
SE2VelocityLimits require care. The proto comment states that "if set, limits the min/max velocity," implying that one should not set values for any directions one does not want limited. However, if any of the numeric fields are not set in the message, they will be interpreted as 0. For example, if angular is not set but linear is, then the message will be incorrectly interpreted as having an angular limit of 0 and the robot will fail to rotate (obviously not the intent). Similarly, if the user only sets say the 'x' field of linear, then 'y' will be incorrectly limited to 0 as well.
- Workaround: Correct usage of the SE2VelocityLimit message requires the user to fully fill out all the fields, setting unlimited values to a large number, say 1e6.
LogAnnotationClient does not include async versions of its RPCs.
- Workaround: If you need to call these in an async manner, call them on a separate thread.
App tokens are no longer required to authorize applications. Instead, each robot itself will be licensed itself. From a programming perspective, this means that it is no longer necessary to load app tokens into the sdk object, or to fill them out in GetAuthTokenRequest.
If a client attempts to call a function for which the robot is not licensed, the robot will respond with an error related to the license issue. The PowerService and GraphNavService responses now include new error codes for license errors on certain actions.
There is a new LicenseClient which can be used to query the license information for a robot. License information can also be queried from the bosdyn.client command line utility.
- The robot previously accepted new commands when there were behavior faults, but did not execute them and would not provide feedback on them. The robot will now reject them with the new status
STATUS_BEHAVIOR_FAULT
. - The python SDK will throw the exception
BehaviorFaultError
. 2.0.0 clients will throw aResponseError
in these cases.
- If the fiducials are not visible, the action will fail with
STATUS_MISSING_FIDUCIALS
. When starting recording or creating a manual waypoint in the GraphNavRecordingService, the client can require certain fiducials to be visible. If the fiducials are not visible, the action will fail withSTATUS_MISSING_FIDUCIALS
. - When recording a map, grated floor mode and ground friction hints that are set in the recording environment are now correctly recorded into the map and used during playback.
- Added an option to the Spot CAM MediaLogService to retrieve the raw (unstitched) images for a log point.
- When a payload is authorized, it is given full access to the services on the robot, rather than a limited set. For example, a payload could now operate Spot.
- Removed some obsolete or internal protobuf messages and service RPCs which were not in use in the SDK.
- Fixed an issue where the SDK would continuously try to request new tokens if it lost connection to the robot at the time when it tried to renew its current user token.
Release 2.0.1 contains the same issues as release 2.0.0, listed below.
If you delete an object from the world object service, there is a chance that a ListWorldObjects call immediately afterward may still include that object.
- Workaround: wait a short time before expecting the object to be gone.
If you register a new service with the robot, calling robot.ensure_client to create a client for that service may result in a UnregisteredServiceNameError.
- Workaround: call robot.sync_with_directory() before robot.ensure_client()
SE2VelocityLimits require care. The proto comment states that "if set, limits the min/max velocity," implying that one should not set values for any directions one does not want limited. However, if any of the numeric fields are not set in the message, they will be interpreted as 0. For example, if angular is not set but linear is, then the message will be incorrectly interpreted as having an angular limit of 0 and the robot will fail to rotate (obviously not the intent). Similarly, if the user only sets say the 'x' field of linear, then 'y' will be incorrectly limited to 0 as well.
- Workaround: Correct usage of the SE2VelocityLimit message requires the user to fully fill out all the fields, setting unlimited values to a large number, say 1e6.
LogAnnotationClient does not include async versions of its RPCs.
- Workaround: If you need to call these in an async manner, call them on a separate thread.
- Example that utilizes the 360-degree Ricoh Theta camera during an Autowalk mission.
- Example that shows how to upload a file to a Google Cloud Platform (GCP) bucket or an Amazon Web Services (AWS) S3 bucket.
- Updated to account for the additional state metrics that are reported. Older versions of this example may fail when connecting to updated robots.
- Added support for viewing the WebRTC stream.
- The example script does not localize itself to any map, but assumes the robot is already localized or that the mission has a localization node in it.
- It verifies that an estop is properly connected before trying to run the mission.
- It contains an additional --timeout parameter that can be used to set an overall time limit on mission execution.
- Can add relocalization nodes to a mission.
- Fixed a UI crash on MacOS X.
The APIs used by Autowalk are now accessible to developers.
- Overall conceptual documents
- GraphNavService: Upload and download maps of the environment, update localizations to that map, and command the robot to autonomously navigate to a location in the map. Example usage can be found in
graph_nav_command_line.py
. Examples of interpreting the map data can be found ingraph_nav_view_map.py
- GraphNavRecordingService: Record maps while the robot walks around. Example usage found in
recording_command_line.py
- MissionService: Load and play autonomous missions. Example mission creation is shown in
mission_recorder.py
with upload and playback usage shown inreplay_mission.py
- RemoteMissionService: A new method for handling mission callbacks, where the mission can trigger user code via an RPC. For building your own callbacks, see the examples in remote_mission_service.
Control and query all hardware features of the Spot CAM. For examples of using each service, see the Spot CAM command line example.
- CompositorService and StreamQualityService: change the layout and quality of the webrtc stream.
- PtzService: Direct PTZ cameras to desired poses.
- LightingService: Control the individual brightness of the illuminator LEDs.
- MediaLogService: Save and retrieve high-resolution images to and from the internal USB drive for later processing.
- AudioService: Upload and play sounds over the Spot CAM speakers.
- NetworkService: Adjust networking settings.
- HealthService, VersionService, PowerService: Query the status of the hardware and software, and power components on and off.
Payloads with a compute component can self-register with Spot and API services
- DirectoryRegistrationService: Allows end users to register new gRPC services running on a payload into the robots service directory. This allows for communicating through the robot’s proxy to the service from off-robot, and for registering mission callbacks for integrations with Autowalk missions. See
directory_modification.py
for example usage. - PayloadRegistrationService: Payloads can now register themselves with the robot, providing their properties and awaiting authorization from a robot administrator. See the self_registration and payloads examples for how to register your own payload.
Learn more about how Spot is perceiving the world around it.
- WorldObjectService: Request details of any objects that has been detected in the world, and add your own detections. Example usage can be found in
mutate_world_objects.py
,fiducial_follow.py
, andadd_image_coordinates.py
. - LocalGridService: Request maps of the area around the robot, including terrain height and obstacle classification. Example usage shown by the bosdyn.client command line utility and the
basic_streaming_visualizer.py
example. - depth_in_visual_frame image sources. These depth map images have the same dimension, extrinsics, and intrinsics as the grayscale image sources, which can help with pixel-depth correspondence issues.
- Python QuickStart has been revamped to streamline getting up and running on the SDK.
- Conceptual documentation has been added to explain key ideas on how to develop for Spot.
- Payload developers guide has been added.
- Generated documents of the API protocol have also been added.
- Reduced API request overhead by several hundred bytes/request.
- TimeSync estimator more resilient to outlier latencies and temporary network outages.
- PowerState: Overall charge percentage and estimated runtime.
- KinematicState: Body velocities are now available in KinematicState.
- RobotState: Foot contact state (in contact vs. not in contact).
- Can now disable various low-level locomotion defaults for special situations and terrain (stair tracking, pitch limiting, cliff avoidance).
- Body rotation can be specified as an offset to nominal or to horizontal.
- See more details in the Breaking Changes section.
- Downloading of depth images supported. Depth maps will be written to PGM files.
- Directory listing has improved formatting.
Version 2.0 contains several breaking changes. While some clients and programs written for the version 1.* SDK may still work, expect some updates to be necessary for most programs.
Documentation of frames on Spot:
- Documentation of frames on Spot (link):
- The Frame message (
geometry.proto
) and FrameType have been deprecated, and the frame is now described as a string throughout the API. - When receiving data from the robot (robot state, images, grid maps, world objects, etc.), the data will come with a string describing the frame it is represented in, but also a FrameTreeSnapshot message which describes how to transform the data into other frames.
- Use the helpers in
frame_helpers.py
(in particularget_a_tform_b
) to compute appropriate transforms for your use case. Seeframe_trajectory_command.py
for an example of using transforms to command the robot. - Code written for version 1 will need to update to the following new convention:
Version 1 frame enum | Version 2 frame string | frame_helpers.py constant |
---|---|---|
FRAME_KO | “odom” | ODOM_FRAME_NAME |
FRAME_VO | “vision” | VISION_FRAME_NAME |
FRAME_BODY | “body” | BODY_FRAME_NAME |
New RpcError exceptions can be raised during RPC calls. If you were already catching RpcErrors, you will catch these. If you were catching individual subclasses, be aware of these new ones.
- PermissionDeniedError
- ResponseTooLargeError
- NotFoundError
- TransientFailureError
There are some new exceptions that can be thrown due to errors with the request before any RPC is made. They generally indicate programmer error, so depending on your use case it may be acceptable to not catch them to find bugs in your program. If it is important to catch all exceptions, be aware that these exist, and all inherit from bosdyn.client.Error
- TimeSyncRequired
- NoSuchLease
- LeaseNotOwnedByWallet
When creating clients or channels from a Robot object, a new class of exceptions inheriting from RobotError may be raised. NonexistentAuthorityError is no longer thrown, but other RpcErrors may be raised.
- UnregisteredServiceError
- UnregisteredServiceNameError
- UnregisteredServiceTypeError
Robot command client will throw a new error if a frame is specified that the robot does not recognize.
- UnknownFrameError
- Trajectories must now specify the frame name in the parent message instead of the trajectory itself.
- Trajectory commands can no longer be specified in a body frame since the output behavior can be ambiguous.
- Robot command messages were split into different proto files (basic_command, full_body_command), which will change import/include paths.
- ‘vel’ field in SE3TrajectoryPoint renamed to velocity (
trajectory.proto
) - Updates in
Payload.proto
- LabelPrefix field was changed from String to Repeated String
- body_T_payload renamed to body_tform_payload
- mount_T_payload renamed to mount_tform_payload
- All Frame messages have been replaced by frame strings where applicable.
- AddLogAnnotationResponse does not have a status field anymore, errors are encoded in the message header information
- ko_tform_body, vo_tform_body, and ground_plane_rt_ko in Kinematic state have been replaced with the transforms_snapshot.
- The SampleCommon message for image captures has been replaced by acquisition time and a FrameTreeSnapshot.
- bosdyn-client has added a dependency on numpy
- Autowalk missions and maps recorded with version 1.1 are not compatible with version 2.0
If you delete an object from the world object service, there is a chance that a ListWorldObjects call immediately afterward may still include that object.
- Workaround: wait a short time before expecting the object to be gone.
If you register a new service with the robot, calling robot.ensure_client to create a client for that service may result in a UnregisteredServiceNameError.
- Workaround: call robot.sync_with_directory() before robot.ensure_client()
SE2VelocityLimits require care. The proto comment states that "if set, limits the min/max velocity," implying that one should not set values for any directions one does not want limited. However, if any of the numeric fields are not set in the message, they will be interpreted as 0. For example, if angular is not set but linear is, then the message will be incorrectly interpreted as having an angular limit of 0 and the robot will fail to rotate (obviously not the intent). Similarly, if the user only sets say the 'x' field of linear, then 'y' will be incorrectly limited to 0 as well.
- Workaround: Correct usage of the SE2VelocityLimit message requires the user to fully fill out all the fields, setting unlimited values to a large number, say 1e6.
LogAnnotationClient does not include async versions of its RPCs.
- Workaround: If you need to call these in an async manner, call them on a separate thread.
- Register, update, and unregister a service.
- Renamed from
get_payload
. - Expanded to show payload version handling.
- Example showing how to set up a payload that registers itself with the robot, hosts a service, and registers its service with the robot.
add_image_coordinates_to_scene (Renamed to world_object_with_image_coordinates in 2.1.0)
- Example using the API demonstrating adding image coordinates to the world object service.
- New EstopNoGui as a command-line addition to the GUI version of the E-Stop example.
get_depth_plus_visual_image (Removed in 2.1.0)
- Example demonstrates how to use the new depth_in_visual_frame image sources to visualize depth in a fisheye image.
- Example program demonstrates how to retrieve information about the state of the currently-running mission.
- Example program shows how to retrieve Spot's location in both the visual and odometry frames. Using these frames, the program shows how to build and execute a command to move Spot to that location plus 1.0 in the x-axis.
- Example demonstrates 3 different methods for working with Spot asynchronous functions.
- Example demonstrate how to use the world object service to list the objects Spot can detect, and filter these lists for specific objects or objects after a certain time stamp.
- Command line interface for graph nav with options to download/upload a map and to navigate a map.
- Example shows how to load and view a graph nav map.
- Example with an interface for operating Spot with your keyboard, recording a mission, and saving it.
- Run a gRPC server that implements the RemoteMissionService service definition.
- Connect a RemoteClient directly to that server.
- Build a mission that talks to that server.
- Example on how to replay a mission via the API.
- Examples to demonstrate how to interact with the Spot CAM.
- Example to visualize Spot's perception scene in a consistent coordinate frame.
- Examples to demonstrate how to use the world object service to add, change, and delete world objects.
- Added support for Windows driver.
-
Missions API Beta and Callbacks When an Autowalk Mission is created with a "Callback" event, a client can detect that change using a beta version of the Mission API, then tell the robot to continue or abort the Mission. Example uses include a sensor payload that detects Callback events and captures sensor information before advancing the mission, and a desktop UI which waits for the user to push a button before advancing the mission.
-
External Forces Beta. Mobility commands can specify how to handle external forces. Examples of external forces could include an object that Spot is towing, or an object Spot is pushing. The default behavior is to do nothing, but clients can specify whether Spot should estimate external forces and compensate for it, or explicitly specify what the external forces are.
-
Depth image extrinsics are fixed. In earlier 1.1.x releases, the extrinsics were incorrectly the same as the fisheye cameras.
-
App Token expiration logging. The Python SDK object logs if the app token will expire in the next 30 days.
- mission_question_answerer demonstrates how to build a client which responds to Mission Callbacks.
1.1.1 has no SDK-related changes.
The 1.1.0 SDK software is published under a new software license which can be found in the LICENSE file at the top of the SDK directory.
-
ImageService exposes depth maps from on-board stereo cameras as additional image sources. Image Sources specify an ImageType to differentiate depth maps from grayscale images.
-
PayloadService is a new service which lists all known payloads on the robot.
-
SpotCheckService is a new service which runs actuator and camera calibration.
-
E-Stop soft timeouts. In prior software release, E-Stop endpoints which stopped checking in would result in the power to the robot's motors being cut immediately. Now the E-Stop endpoint can be configured so Spot will attempt to sit followed by cutting power. The timeout parameter for an E-Stop endpoint specifies when the sitting behavior starts, and the cut_power_timeout parameter specifies when the power will cut off.
-
TerrainParams can be added to MobilityParams to provide hints about the terrain that Spot will walk on. The coefficient of friction of the ground can be specified. Whether the terrain is grated metal can also be specified.
-
Log Annotations a new type of log: Blob for large binary data.
The sample code directory structure has changed to directory-per-example under python/examples. Each example includes a requirements.txt file for specifying dependencies.
-
estop is a desktop GUI which creates an E-Stop endpoint for a robot. This example demonstrates how to use the E-Stop endpoint system, and is a useful utility on its own.
-
follow_fiducial is an example where Spot will follow an AprilTag fiducial that it can see in its on-board cameras. This demonstrates how to use camera extrinsics and intrinsics to convert pixels to world coordinates, and how to use the trajectory commands.
-
get-image is a simple example to retrieve images from Spot and save them to disk. It shows how to use the basics of the image service.
-
get-payload is a simple example which lists all of the payloads on the robot. It shows how to use the payload service.
-
get_robot_state is a simple example to retrieve robot state.
-
hello_spot is carried over from prior SDK releases. It is an introductory tutorial showing basic use of the Spot SDK.
-
logging demonstrates how to add custom annotations to Spot’s log files.
-
spot_check demonstrates how to use SpotCheck - Spot’s in-the-field calibration behavior.
-
spot_light is a demo where Spot rotates its body while standing to try to face a flashlight seen in its front cameras.
-
spot_tensorflow_detector demonstrates how to integrate the Spot SDK with Tensorflow for object classification from images.
-
time_sync is a simple example demonstrating how to use the TimeSync service.
-
wasd is carried over from prior SDK releases. It is an interactive program which uses keyboard control for the robot, and demonstrates how to use a variety of commands.
-
xbox_controller demonstrates how to specify more advanced options for mobility commands.
-
Too many invalid login attempts will lock a user out from being able to authenticate for a temporary period to prevent brute-force attacks. GetAuthTokenResponse indicates this state with a STATUS_TEMPORARILY_LOCKED_OUT.
-
Elliptic Curve (ECDSA) cryptography used for user tokens - reducing the size of RPC requests by several hundred bytes.
-
gRPC exceptions are correctly handled in Python 3.
-
Command-line tool handles unicode robot nicknames correctly.
-
Command-line tool supports retrieving robot model information (URDF and object files)
-
Command-line tool supports retrieving multiple images at once.
-
“Strict Version” support for software version.
-
App Token paths which include “~” will automatically expand, rather than fail.
-
Mobility Commands which have MobilityParams.vel_limit with only a min or max velocity are correctly handled. In prior releases, these commands would result in no movement at all.
-
Mobility Commands which have BodyControlParams.base_offset_rt_footprint.reference_time in the past result in a STATUS_EXPIRED response rather than a STATUS_INVALID_REQUEST.
-
SE2VelocityCommands with unset slew_rate_limit are correctly handled. In prior releases, an unset slew_rate_limit would result in the robot walking in place.
-
Removed support for Python 2.7. Only Python 3.6+ is supported due to upcoming Python 2 End-of-Life. Windows 10, MacOS, and Ubuntu LTS are still supported.
-
The HINT_PACE LocomotionHint is no longer supported due to physical stability issues. Any commands which specify a HINT_PACE LocomotionHint will be treated like a HINT_JOG LocomotionHint is specified.
-
HINT_AUTO_TROT and HINT_AUTO_AMBLE are deprecated as names - use HINT_SPEED_SELECT_TROT and HINT_SPEED_SELECT_AMBLE respectively going forward.
-
Protocol Buffer locations changed to split services from messages. Any direct imports of protocol buffers by client applications will need to change to support the 1.1.0 version changes.
-
Improved documentation on SDK installation.
-
Clearer Python dependency requirements.
-
RobotId service exposes computer serial number in addition to robot serial number.
-
wasd image capture works in Python 3.
-
Fixed timing bugs in power service.
Initial release of the SDK.