openpilot0/models
Mitchell Goff 42591a19a7 New model: 224877e7-dfcf-4b28-9482-371655918fe1/950 (#23170)
* New model: 224877e7-dfcf-4b28-9482-371655918fe1/950

* Updated model replay ref
old-commit-hash: 1d119999c2
2021-12-08 13:55:30 -08:00
..
README.md Add DM model readme (#22801) 2021-11-08 15:15:55 -08:00
dmonitoring_model.current wider FOV DM on comma three (#22286) 2021-10-13 17:00:46 -07:00
dmonitoring_model.onnx wider FOV DM on comma three (#22286) 2021-10-13 17:00:46 -07:00
dmonitoring_model_q.dlc wider FOV DM on comma three (#22286) 2021-10-13 17:00:46 -07:00
supercombo.dlc New model: 224877e7-dfcf-4b28-9482-371655918fe1/950 (#23170) 2021-12-08 13:55:30 -08:00
supercombo.onnx New model: 224877e7-dfcf-4b28-9482-371655918fe1/950 (#23170) 2021-12-08 13:55:30 -08:00

README.md

Neural networks in openpilot

To view the architecture of the ONNX networks, you can use netron

Supercombo

Supercombo input format (Full size: 393738 x float32)

  • image stream
    • Two consecutive images (256 * 512 * 3 in RGB) recorded at 20 Hz : 393216 = 2 * 6 * 128 * 256
      • Each 256 * 512 image is represented in YUV420 with 6 channels : 6 * 128 * 256
        • Channels 0,1,2,3 represent the full-res Y channel and are represented in numpy as Y[::2, ::2], Y[::2, 1::2], Y[1::2, ::2], and Y[1::2, 1::2]
        • Channel 4 represents the half-res U channel
        • Channel 5 represents the half-res V channel
  • desire
    • one-hot encoded vector to command model to execute certain actions, bit only needs to be sent for 1 frame : 8
  • traffic convention
    • one-hot encoded vector to tell model whether traffic is right-hand or left-hand traffic : 2
  • recurrent state
    • The recurrent state vector that is fed back into the GRU for temporal context : 512

Supercombo output format (Full size: 6472 x float32)

  • plan

    • 5 potential desired plan predictions : 4955 = 5 * 991
      • predicted mean and standard deviation of the following values at 33 timesteps : 990 = 2 * 33 * 15
        • x,y,z position in current frame (meters)
        • x,y,z velocity in local frame (meters/s)
        • x,y,z acceleration local frame (meters/(s*s))
        • roll, pitch , yaw in current frame (radians)
        • roll, pitch , yaw rates in local frame (radians/s)
      • probability1 of this plan hypothesis being the most likely: 1
  • lanelines

    • 4 lanelines (outer left, left, right, and outer right): 528 = 4 * 132
      • predicted mean and standard deviation for the following values at 33 x positions : 132 = 2 * 33 * 2
        • y position in current frame (meters)
        • z position in current frame (meters)
  • laneline probabilties

    • 2 probabilities1 that each of the 4 lanelines exists : 8 = 4 * 2
      • deprecated probability
      • used probability
  • road-edges

    • 2 road-edges (left and right): 264 = 2 * 132
      • predicted mean and standard deviation for the following values at 33 x positions : 132 = 2 * 33 * 2
        • y position in current frame (meters)
        • z position in current frame (meters)
  • leads

    • 2 hypotheses for potential lead cars : 102 = 2 * 51
      • predicted mean and stadard deviation for the following values at 0,2,4,6,8,10s : 48 = 2 * 6 * 4
        • x position of lead in current frame (meters)
        • y position of lead in current frame (meters)
        • speed of lead (meters/s)
        • acceleration of lead(meters/(s*s))
      • probabilities1 this hypothesis is the most likely hypothesis at 0s, 2s or 4s from now : 3
  • lead probabilities

    • probability1 that there is a lead car at 0s, 2s, 4s from now : 3 = 1 * 3
  • desire state

    • probability1 that the model thinks it is executing each of the 8 potential desire actions : 8
  • meta 2

    • Various metadata about the scene : 80 = 1 + 35 + 12 + 32
      • Probability1 that openpilot is engaged : 1
      • Probabilities1 of various things happening between now and 2,4,6,8,10s : 35 = 5 * 7
        • Disengage of openpilot with gas pedal
        • Disengage of openpilot with brake pedal
        • Override of openpilot steering
        • 3m/(s*s) of deceleration
        • 4m/(s*s) of deceleration
        • 5m/(s*s) of deceleration
      • Probabilities1 of left or right blinker being active at 0,2,4,6,8,10s : 12 = 6 * 2
      • Probabilities1 that each of the 8 desires is being executed at 0,2,4,6s : 32 = 4 * 8
  • pose 2

    • predicted mean and standard deviation of current translation and rotation rates : 12 = 2 * 6
      • x,y,z velocity in current frame (meters/s)
      • roll, pitch , yaw rates in current frame (radians/s)
  • recurrent state

    • The recurrent state vector that is fed back into the GRU for temporal context : 512

Driver Monitoring Model

  • .onnx model can be run with onnx runtimes
  • .dlc file is a pre-quantized model and only runs on qualcomm DSPs

input format

  • single image (640 * 320 * 3 in RGB):
    • full input size is 6 * 640/2 * 320/2 = 307200
    • represented in YUV420 with 6 channels:
      • Channels 0,1,2,3 represent the full-res Y channel and are represented in numpy as Y[::2, ::2], Y[::2, 1::2], Y[1::2, ::2], and Y[1::2, 1::2]
      • Channel 4 represents the half-res U channel
      • Channel 5 represents the half-res V channel
    • normalized, ranging from -1.0 to 1.0

output format

  • 39 x float32 outputs (parsing example)
    • face pose: 12 = 6 + 6
      • face orientation [pitch, yaw, roll] in camera frame: 3
      • face position [dx, dy] relative to image center: 2
      • normalized face size: 1
      • standard deviations for above outputs: 6
    • face visible probability: 1
    • eyes: 20 = (8 + 1) + (8 + 1) + 1 + 1
      • eye position and size, and their standard deviations: 8
      • eye visible probability: 1
      • eye closed probability: 1
    • wearing sunglasses probability: 1
    • poor camera vision probability: 1
    • face partially out-of-frame probability: 1
    • (deprecated) distracted probabilities: 2
    • face covered probability: 1

  1. All probabilities are in logits, so you need to apply sigmoid or softmax functions to get actual probabilities ↩︎

  2. These outputs come directly from the vision blocks, they do not have access to temporal state or the desire input ↩︎