Split trial analysis reveals the information capacity of neural population codes

Understanding how correlated neural noise affects neural population coding represents one basic question in computational and systems neuroscience. Recent theoretical work suggest that shared noise along the stimulus encoding direction is the primary factor that limits information encoding (i.e., information-limiting noise). Despite this theoretical insight, it has been difficult to test experimentally due to the challenges in inferring information-limiting noise from neural data. To overcome this challenge, we have developed a method (i.e., split-trial analysis) based on partitioning the neural population response of an individual trial. Results from extensive numerical simulations suggest that split-trial analysis substantially outperforms existing methods in accuracy, efficiency, and robustness. Notably, it does so without estimating the noise covariance matrix, which represents a major barrier for prior studies. Applications of split-trial analysis to a number of neurophysiological datasets reveals insights into the precision of the neural codes for several systems. First, it reveals a substantial amount of information-limiting noise in the head direction system in mice. Second, it suggests a small yet positive information-limiting noise in the orientation code in mouse V1. Third, it reveals that the information-limiting noise in the macaque prefrontal cortex is highly consistent over time during a simple saccade task. Split-trial analysis is a general technique that should be widely applicable in analyzing the properties of population codes in the brain.