Time Makes Space: Emergence of Place Fields in Networks Encoding Temporally Continuous Sensory Experiences

Zhaoze Wang, Ronald W Di Tullio, Spencer Rooke, Vijay Balasubramanian
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Abstract

The vertebrate hippocampus is believed to use recurrent connectivity in area CA3 to support episodic memory recall from partial cues. This brain area also contains place cells, whose location-selective firing fields implement maps supporting spatial memory. Here we show that place cells emerge in networks trained to remember temporally continuous sensory episodes. We model CA3 as a recurrent autoencoder that recalls and reconstructs sensory experiences from noisy and partially occluded observations by agents traversing simulated arenas. The agents move in realistic trajectories modeled from rodents and environments are modeled as continuously varying, high-dimensional, sensory experience maps (spatially smoothed Gaussian random fields). Training our autoencoder to accurately pattern-complete and reconstruct sensory experiences with a constraint on total activity causes spatially localized firing fields, i.e., place cells, to emerge in the encoding layer. The emergent place fields reproduce key aspects of hippocampal phenomenology: a) remapping (maintenance of and reversion to distinct learned maps in different environments), implemented via repositioning of experience manifolds in the network's hidden layer, b) orthogonality of spatial representations in different arenas, c) robust place field emergence in differently shaped rooms, with single units showing multiple place fields in large or complex spaces, and d) slow representational drift of place fields. We argue that these results arise because continuous traversal of space makes sensory experience temporally continuous. We make testable predictions: a) rapidly changing sensory context will disrupt place fields, b) place fields will form even if recurrent connections are blocked, but reversion to previously learned representations upon remapping will be abolished, c) the dimension of temporally smooth experience sets the dimensionality of place fields, including during virtual navigation of abstract spaces.
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时间创造空间:时空连续感官体验编码网络中地点场的出现
脊椎动物的海马区被认为是利用 CA3 区的递归连接来支持通过部分线索回忆外显记忆。该脑区还含有位置细胞,其位置选择性发射场实现了支持空间记忆的映射。在这里,我们展示了位置细胞出现在训练有素的网络中,以记忆时间上连续的感觉事件。我们将 CA3 建模为一个递归自动编码器,该编码器可通过穿越模拟竞技场的代理,从嘈杂和部分遮蔽的观察结果中回忆和重建感官体验。代理以啮齿类动物的真实轨迹移动,而环境则被模拟为连续变化的高维感官经验图(空间平滑高斯随机场)。通过训练我们的自动编码器来精确地完成模式化和重建感官体验,并对总活动进行约束,从而在编码层中出现空间定位的发射场,即场所细胞。出现的场所场再现了海马现象学的关键方面:a)重映射(在不同环境中保持和还原到不同的已学地图),通过在网络的隐藏层中重新定位经验流形来实现;b)不同场域中空间表征的正交性;c)在不同形状的房间中出现稳健的场所场,单个单元在大型或复杂空间中显示多个场所场;d)场所场缓慢的表征漂移。我们认为,这些结果的出现是因为空间的连续穿越使感官体验具有时间连续性。我们提出了可检验的预测:a) 快速变化的感官环境会破坏场所场;b) 即使循环连接被阻断,场所场也会形成,但在重映射时还原到先前学习的表征的情况将被取消;c) 时间上平滑的体验维度设定了场所场的维度,包括在抽象空间的虚拟导航过程中。
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