It was suggested that glutamate concentration at the synaptic terminal of the cones was controlled primarily by a voltage-dependent glutamate transporter and that diffusion played a less important role. The conclusion was based on the observation that the rate of glutamate concentration during the hyperpolarizing light response was dramatically slowed when the transporter was blocked with dihydrokainate although diffusion remained intact. To test the validity of this notion we constructed a model in which the balance among uptake, diffusion, and release determined the flow of glutamate into and out of the synaptic cleft. The control of glutamate concentration was assumed here to be determined by two relationships; 1) glutamate concentration is the integral over the synaptic volume of the rates of release, uptake, and diffusion, and 2) membrane potential is the integral over the membrane capacitance of the dark, leak, and transporter-gated chloride current. These relationships are interdependent because glutamate uptake via the transporter is voltage dependent and because the transporter-gated current is concentration dependent. The voltage and concentration dependence of release and uptake, as well as the light-elicited, transporter-gated, and leak currents were measured in other studies. All of these measurements were incorporated into our predictive model of glutamate uptake. Our results show a good quantitative fit between the predicted and the measured magnitudes and rates of change of glutamate concentration, derived from the two interdependent relationships. This close fit supports the validity of these two relationships as descriptors of the mechanisms underlying the control of glutamate concentration, it verifies the accuracy of the experimental data from which the functions used in these relationships were derived, and it lends further support to the notion that glutamate concentration is controlled primarily by uptake at the transporter.