Arbor's Instant Video Doorbell is a decent first product, injecting a bit of competition into a market dominated by Ring. It has some advantages over its more famous competitor and is especially interesting if your home lacks doorbell wiring, but the system needs a more work if it's to really impress. Its manufacturer makes some bold claims about the product, saying it's "the world's most advanced," "has the best and fastest picture," the "most reliable WiFi connection on the market" and that users will get "no false alarms with Arbor's superior motion detector." I found none of that to be true. The last claim is particularly foolhardy as no video doorbell or smart security camera I've tested has been completely free of false alarms.

I consider a topographic projection between two neuronal layers with different densities of neurons. Given the number of output neurons connected to each input neuron (divergence or fan-out) and the number of input neurons synapsing on each output neuron (convergence or fan-in) I determine the widths of axonal and dendritic arbors which minimize the total volume ofaxons and dendrites. My analytical results can be summarized qualitatively in the following rule: neurons of the sparser layer should have arbors wider than those of the denser layer. This agrees with the anatomical data from retinal and cerebellar neurons whose morphology and connectivity are known. The rule may be used to infer connectivity of neurons from their morphology.

I consider a topographic projection between two neuronal layers with different densities of neurons. Given the number of output neurons connected to each input neuron (divergence or fan-out) and the number of input neurons synapsing on each output neuron (convergence or fan-in) I determine the widths of axonal and dendritic arbors which minimize the total volume ofaxons and dendrites. My analytical results can be summarized qualitatively in the following rule: neurons of the sparser layer should have arbors wider than those of the denser layer. This agrees with the anatomical data from retinal and cerebellar neurons whose morphology and connectivity are known. The rule may be used to infer connectivity of neurons from their morphology.

I consider a topographic projection between two neuronal layers with different densitiesof neurons. Given the number of output neurons connected toeach input neuron (divergence or fan-out) and the number of input neurons synapsing on each output neuron (convergence or fan-in) I determine the widths of axonal and dendritic arbors which minimize the total volume ofaxons and dendrites. My analytical results can be summarized qualitativelyin the following rule: neurons of the sparser layer should have arbors wider than those of the denser layer. This agrees with the anatomical data from retinal and cerebellar neurons whose morphology andconnectivity are known. The rule may be used to infer connectivity ofneurons from their morphology.