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Related Concept Videos

Reinforcement Schedules01:24

Reinforcement Schedules

Positive reinforcement is a powerful method for teaching new behaviors to both animals and humans. B.F. Skinner demonstrated this with his experiments using rats in a Skinner box. When a rat pressed a lever, it received a food pellet. This immediate reward encouraged the rat to repeat the behavior. This method, where a reward follows every instance of the behavior, is known as continuous reinforcement. It is highly effective for establishing new behaviors quickly.
Once a behavior is learned,...
Timing and Consequences on Behavior01:08

Timing and Consequences on Behavior

In operant conditioning, the timing of reinforcement is crucial. For animals like rats and cats, immediate reinforcement (within a few seconds) is much more effective than delayed reinforcement. For example, a food reward for a rat needs to follow within 30 seconds of pressing a bar to be effective. 
Humans, however, can respond to delayed reinforcers. We often make decisions between immediate small rewards and delayed larger rewards. This ability to delay gratification is a significant factor...

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Related Experiment Video

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Three Laboratory Procedures for Assessing Different Manifestations of Impulsivity in Rats
09:12

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Published on: March 17, 2019

Interresponse time structures in variable-ratio and variable-interval schedules.

Matthew T Bowers1, Jade Hill, William L Palya

  • 1Department of Psychology, Jacksonville State University, Jacksonville, AL 36265, USA.

Journal of the Experimental Analysis of Behavior
|December 17, 2008
PubMed
Summary
This summary is machine-generated.

Pigeon key pecking behavior under different schedules showed varied response time patterns. Variable-interval schedules produced continuous distributions, unlike other schedules, challenging common analysis methods.

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Area of Science:

  • Behavioral science
  • Animal behavior
  • Operant conditioning

Background:

  • Understanding interresponse times (IRTs) is crucial for analyzing operant behavior.
  • Previous research often assumes dichotomous engagement and disengagement bouts.
  • Log survivor analysis and double exponential fits are common IRT analysis methods.

Purpose of the Study:

  • To investigate the interresponse-time structures of pigeon key pecking under various reinforcement schedules.
  • To assess the applicability of standard IRT analysis methods across different schedules.
  • To determine if operant behavior can be consistently dichotomized into engagement and disengagement.

Main Methods:

  • Pigeons were subjected to three reinforcement schedules: variable-ratio, variable-interval, and variable-interval plus linear feedback.
  • Interresponse times were systematically recorded and analyzed for each schedule.
  • Data were examined for patterns indicative of distinct engagement and disengagement periods.

Main Results:

  • Variable-ratio and variable-interval plus linear feedback schedules produced distinct short IRTs and broader distributions of longer IRTs.
  • Variable-interval schedules, however, yielded a more continuous distribution of interresponse times.
  • These differing patterns suggest schedule-dependent variations in behavior structure.

Conclusions:

  • The structure of interresponse times varies significantly across different reinforcement schedules.
  • A log survivor analysis or double exponential fit may not be universally applicable for dichotomizing operant behavior.
  • Findings challenge the assumption of consistent engagement/disengagement bouts in pigeon key pecking behavior.