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Divide And Conquer

One of the main criticisms of control systems based on Sense-Plan-Act is that they are too slow, because planning is too slow. Thus, planning can only be applied to higher levels of an agent architecture where it can deliberate at length over how best to achieve high-level goals, and then send the plan off to an executive for execution. The executive will not plan, and so it can be much faster. However, the executive must now be programmed by hand to properly decompose higher-level plans into lower-level commands.

A key idea behind T-REX is that an agent is not just a single monolithic controller. In practice, it is both feasible and desirable to break up the control structure into a collection of semi-independent control loops, each with it's own internal SPA cycle. Intuitively, this is feasible in many applications because:

In T-REX terminology, this means that the agent control structure can be divided into a collection of Teleo-Reactors where each one is configured with a different functional scope (i.e. the set of timelines it considers) and temporal scope (i.e. the planning horizon over which it finds plans. This factored control structure is highly desirable because:

The Compositional Nature of a Teleo-Reactor

The symmetry of inbound and outbound goals and observations enables natural composition of reactors. This is shown below with a 4 reactor configuration. The internal details of a reactor are irrelevant. Reactor A is the top-level reactor. It can dispatch goals and observations to other reactors (i.e. reactors B and C). It's goals originate outside the agent. Both B and C interact with D. Thus, the aggregate control structure is partitioned into a collection of reactors. Goals flow top down. Observations flow bottom up. Note that observations for a single timeline may be published to more than one reactor, and goals for a given timeline can be dispatched from more than one reactor.

composition.png

Timeline ownership to direct information flow unambiguosly

T-REX defines an ownership and usage model of timelines to make the composition of reactors explicit, and the rules for information flow and conflict resolution unambiguous. If a reactor owns a timeline, it is solely responsible for deciding what value that timeline has as execution unfolds. Such timelines are internal to that reactor. If a reactor uses a timeline, it will receive new values for that timeline as they arise, and it may dispatch any goals it has for that timeline to the owner reactor. Such a timeline is external to its user. The user of a timeline depends on it's owner. This dependency dictates the flow of information in T-REX. The key to scalability is that the scope of computation for each reactor is restricted to only the set of timelines it explicitly owns or uses, over the time horizon it cares to deliberate. This modularity, coupled with the dependency directed information flow, makes T-REX amenable to divide-and-conquer strategies to scale up to larger scale systems efficiently in a unified computational framework.

An Example

We will now illustrate the compositional approach using PR2, a sophisticated mobile manipulation platform designed for use in indoor environments. In June, 2009, a PR2 completed Milestone 2, a challenging autonomy triathalon involving navigation, opening doors, and plugging itself in to a standard electrical outlet. T-REX was used as the executive.

Reactor Graph

The reactor graph is shown below. It depicts the set of reactors and dependencies between them. Each reactor and its dependent links are color-coded. Goals flow in the direction of these links. Observations flow in the reverse direction. Each reactor is annotated with a name, its look-ahead indicating how far ahead to plan, its latency giving an upper bound on plan completion time, and parameters i and e indicating the number of internal and external timelines respectively. A look-ahead of H indicates the reactor plans for the entire agent horizon. A latency of 0 indicates that planning must complete before the next tick.

reactorgraph.png

The Robot Control Subsystem has no external timelines. It is mapped to a single exogenous state variable giving the planar pose of the robot, as well as each of 25 external action primitives for doing things like grasping a handle, moving the base, pushing the door. This reactor is implemented as an adapter mapping ROS messages to goal requests, recalls and observations. All other reactors were instances of a Deliberative Reactor varying in their functional and temporal scopes. Real-time controller configuration management was handled in the Mechanism Control reactor. The Doorman encapsulated behavior for navigating doorways. The Driver was used for navigation in all other regions (i.e. offices, hallways and open areas). The Navigator enacapsulated planar navigation and doorway traversal, allowing higher level systems to reason about simply getting to a point in the building. The Recharger encapsulated all behavior for plugging in and unplugging. At the top level, the Master was used to plan the overall tour given high-level goals, and decompose these goals into successive calls to the Navigator and Recharger. The State Estimator monitored execution to track a number of variables of interest for ensuring PR2 safety and enabled these variables to be shared by reactors.

Inside the Master reactor

The screen shot below is from the Execution Monitor which is used to observe T-REX state during execution. The panels on the left indicate the set of all reactors and the one that is in view. In this case, it is the Master. The timelines contained within the Master reactor are also displayed. All times shown are earliest start and earliest end. The execution frontier is at tick 9. In this case, the set of top-level goals are on the m2_goals timeline, which delegates to the navigator and recharger. Notice that the recharger is in the active state.

master.png

Inside the Mechanism Control reactor

The screen shot below is for the Mechanism Control reactor for the same tick (9). Note the correspondence between planned states for the various mechanism timelines and the activation states of the switch_controllers timeline. Each transition is achieved by execution of a switch_controller action.

mechanism_control.png


2024-11-23 17:57