Visual Stimuli
When designing operant behaviour assays in systems neuroscience, it is useful to describe the task as a sequence of states that the system goes through (e.g. stimulus on, stimulus off, reward, inter-trial interval, etc). Progression through these states is driven by events, which can be either internal or external to the system (e.g. button press, timeout, stimulus offset, movement onset). It is common to describe the interplay between states and events in the form of a finite-state machine diagram, or graph, where nodes are states, and arrows are events.
For example, a simple reaction time task where the subject needs to press a button as fast as possible following a stimulus is described in the following diagram:
The task begins with an inter-trial interval (ITI), followed by stimulus presentation. After stimulus onset, advancement to the next state can happen only when the subject presses the button (success trial) or a timeout elapses (miss trial). Depending on which event is triggered first, the task advances either to the reward state, or missed state. At the end, the task goes back to the beginning of the ITI state for the next trial.
The exercises below will show you how to translate the above diagram of states and events into an equivalent Bonsai workflow, which can be easily adapted and modified to describe many different operant behaviour tasks.
Exercise 1: Declaring and configuring the render loop
In this worksheet, we will be using an Arduino or a camera as an interface to detect external behaviour events. For experimental purposes, it is very helpful to record and timestamp all of these events, independently of which state the task is in.
- Connect a digital sensor (e.g. beam-break, button, TTL) into Arduino pin 8.
- Insert a
DigitalInput
source and set it to Arduino pin 8. - Insert a
Timestamp
combinator. - Insert a
CsvWriter
sink and configure itsFileName
property with a file name ending in.csv
. - Run the workflow and activate the digital sensor a couple of times. Stop the workflow and confirm that the events were successfully timestamped and logged in the
.csv
file.
Exercise 2: Inter-trial interval and stimulus presentation
Translating a state machine diagram into a Bonsai workflow begins by identifying the initial state of the task (i.e. the beginning of each trial). It is often convenient to consider the inter-trial interval period as the initial state, followed by stimulus presentation.
- Insert a
Timer
source and set itsDueTime
property to be about 3 seconds. - Insert a
Sink
operator and set itsName
property toStimulusOn
. - Double-click on the
Sink
node to open up its internal specification.
The Sink
operator allows you to specify arbitrary processing side-effects without affecting the original flow of events. It is often used to trigger and control stimulus presentation in response to events in the task. Inside the internal specification, Source1
represents input events arriving at the sink. In the specific case of Sink
operators, the WorkflowOutput
node can be safely ignored.
- Insert a
Boolean
operator followingSource1
and set itsValue
property toTrue
. - Insert a
DigitalOutput
sink and connect it to Arduino pin 13. - Run the workflow a couple of times and verify that the sequence of events is progressing correctly.
Note: Opening a new connection to the Arduino can take several seconds due to the way the Firmata protocol is implemented. This may introduce a slight delay in starting the task. This delay is only present at the start of the workflow and will not affect the behavior of the state machine.
- In the main top-level workflow, insert a
Delay
operator and set itsDueTime
property to a couple of seconds. - Copy the
StimulusOn
operator and insert it after theDelay
(you can either copy-paste or recreate it from scratch). - Rename the new operator to
StimulusOff
and double-click it to open up its internal representation. - Set the
Value
property of theBoolean
operator toFalse
. - Run the workflow a couple of times. Is it behaving as you would expect?
- Insert a
Repeat
operator after theStimulusOff
. - Run the worklow. Can you describe in your own words what is happening?
- Optional: Draw a marble diagram for
Timer
,StimulusOn
,Delay
, andRepeat
.
Exercise 3: Driving state transitions with external behaviour events
- Delete the
Delay
operator. - Insert a
SelectMany
operator afterStimulusOn
, and set itsName
property toResponse
. - Double-click on the
SelectMany
node to open up its internal specification.
The SelectMany
operator is used here to create a new state for every input event. Source1
represents the input event that created the state, and WorkflowOutput
will be used to report the end result from the state (e.g. whether the response was a success or failure).
- Insert a
DigitalInput
source and set it to Arduino pin 8. - Insert a
Take
operator and set itsCount
property to 1. - Insert a
Boolean
operator and set itsValue
property toTrue
. - Delete the
Source1
operator. - Connect the
Boolean
operator toWorkflowOutput
. - Run the workflow a couple of times. Is it behaving as you would expect?
Exercise 4: Timeout and choice
- Still inside the
SelectMany
, insert aTimer
source and set itsDueTime
property to be about 1 second. - Insert a
Boolean
operator and set itsValue
property toFalse
. - Insert the
Amb
combinator and connect to it both of theBoolean
operators. - Connect the output of
Amb
toWorkflowOutput
. - Run the workflow a couple of times, open the visualizer of the
Response
node, and describe what is being plotted.
Exercise 5: Specifying conditional task outcomes
-
Insert a
Condition
operator after theStimulusOff
node, and set itsName
property toSuccess
. - Insert another
Condition
operator in a new branch off theStimulusOff
node, and set itsName
property toMiss
. - Double-click on the
Condition
operator to open up its internal specification. -
Insert a
BitwiseNot
operator afterSource1
. - In the top-level workflow, insert a
Merge
operator and connect to it the outputs of both conditional branches.