Physics 434, 2015: Homework 9
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Please turn on the assignment either as a PDF file to me by email, or as a printout/writeup to my mailbox in physics. Detailed derivations (with explanations) and calculations must be present for the problems for full credit. Submit your code if a problem requires you to program.
Undergraduates
- Problem 11.1
- What is the differential entropy of an exponential distribution?
- How much information can a spiking neuron transmit? This is limited from above by its entropy rate. Let's represent a neuron as releasing action potentials with a Poisson process with a certain rate , and let's calculate the entropy rate of the Poisson process. First represent this process by discretizing time in intervals . Explain why the entropy of the Poisson generated sequence of duration (or, alternatively, symbols) is exactly proportional to time, that is , where is some constant. Thus we only need to calculate the entropy of a single symbol, this , in order to find the entropy rate as . Does this rate have a finite value as ? Why or why not? Estimate the maximum bitrate of a neuron that can control placement of its spikes to the accuracy of 1 ms.
Graduate Students
- Problem 11.3
- What is the differential entropy of an exponential distribution?
- How much information can a spiking neuron transmit? This is limited from above by its entropy rate. Let's represent a neuron as releasing action potentials with a Poisson process with a certain rate , and let's calculate the entropy rate of the Poisson process. First represent this process by discretizing time in intervals . Explain why the entropy of the Poisson generated sequence of duration (or, alternatively, symbols) is exactly proportional to time, that is , where is some constant. Thus we only need to calculate the entropy of a single symbol, this , in order to find the entropy rate as . Does this rate have a finite value as ? Why or why not? Estimate the maximum bitrate of a neuron that can control placement of its spikes to the accuracy of 1 ms.
- Suppose now the neuron has what's called a refractory period. That is, after a spike, a neuron cannot fire for the time . What is the entropy rate of such neuron?