Table 1.
Modularity terminology and relationships among descriptions and units
| Marr level of description | Increasingly finer resolution elements of action composition and control | Type of data and description | ||||
|---|---|---|---|---|---|---|
|
Task Behavioral task/Kinematic task/Task planning |
Behavior (e.g., Hunt, groom etc.) | Task: (run to capture); akinematic oscillation | Subtask: (swing, stance, foot placement, reach to grasp) | Stroke/kinematic segmentation unit = kinematic stroke or kinematic primitive | Kinematics | |
|
Algorithms Controls/algorithms (kinetics necessary) |
Timing, rhythm & sequence | d Force pattern for subtask, possible co-articulation | Force pattern for individual kinematic stroke, possible co-articulation | Unit building block for force patterns. Force-field primitives = kinetic primitives | Kinetics | |
| bRhythm generator system | cPattern shaping under rhythm generator, descending and sensory control influences or |
gBurst synergies = motor primitives = force-field primitive. Unitary burst (or “pulse”) of a synchronous muscle synergy |
Muscle patterns | |||
| Rhythm generator system | Pattern shaping system | eTime-varying synergies | ||||
|
Implementation Implementations/circuitry |
Neural oscillator or state chaining system | fNeural switching systems or emergent pattern shaping and sequencing processes | Separated neural premotor drives and burst generation | Neural support | ||
| <=> robotic Dynamical movement primitive (oscillator primitives) or finite state machine | <=> robotic Coupling or selection and switching policy, e.g., finite state machine with time outs | <=> robotic Kinematic primitive and PID controller | <=> robotic Kinetic primitive or multi-joint PD control unit | Sample equivalent idea in biomimetic robotics | ||
Note: Missing from the table are the synergy formulations as optimal controlled subspaces, and controlled/uncontrolled manifolds. The missing terms and models of modularity are harder to relate simply and directly to pattern generation and spinal neural circuits in testable hypotheses. In the table, specific relationships or areas need significant work and are important to understand new data on modularity in stroke and spinal cord injury.
The relations of rhythmic and discrete motion at kinematic and production descriptions remain an area of ambiguity.
As might be expected, rhythm/timing generation mechanisms and circuit location remain insufficiently specified.
The structure of pattern shaping remains difficult and controversial. The separation from rhythm generation is controversial. The composition and modularity of pattern is disputed. Modularity can be considered emergent from network dynamics or based on switching and incorporation of explicit modules.
Efficient kinematic and kinetic action may involve co-articulation of modules in sequences and mechanisms should support this contextual adjustment for increasing skill levels in tasks.
Modules in pattern shaping could be fixed sequences of several bursts, also called time varying synergies, that are explicitly related to kinematic modules such as strokes or cycles. Alternatively, pattern shaping modules could be single bursts, that are not uniquely or closely related to kinematic strokes and cycles (e.g., unit bursts/synchronous synergies that instead relate directly to units of biomechanical modularity such as unitary force-fields, and to neural drive (see g below).
The structure of neural switching and pattern sequencing is very poorly understood but is probably crucial to understand processes of co-articulation, merging, splitting, and sequence changes after neural damage and during therapy.
Neural underpinning of unit bursts and drive structure are also part of the key to these clinically meaningful processes.