High dynamic range imaging pixels with improved readout

What is claimed is: 1. An imaging system, comprising: an array of pixels arranged in rows and columns, each pixel in the array of pixels comprising: a photodiode that accumulates charge in response to incident light; a floating diffusion node coupled to the photodiode via a transfer transistor; a gain select storage node coupled to the floating diffusion node; and readout circuitry coupled to the floating diffusion node, wherein the readout circuitry reads out a first signal while the pixel is in a high gain configuration, wherein the first signal is based on a first portion of the accumulated charge that overflows from the photodiode into the floating diffusion node and the gain select storage node, wherein the readout circuitry reads out a second signal while the pixel is in the high gain configuration, wherein the second signal is based on the first portion of the accumulated charge and based on a second portion of the accumulated charge that is transferred to the floating diffusion node through the transfer transistor, and the pixel is reset in response to the readout circuitry reading out the second signal. 2. The imaging system defined in claim 1 , further comprising: image processing circuitry that receives the first and second signals from the readout circuitry and that generates a high dynamic range signal based on the first and second signals. 3. The imaging system defined in claim 2 , wherein the high dynamic range signal is generated based on the first and second signals and on first and second calibration signals. 4. The imaging system defined in claim 3 , wherein the first calibration signal is dark offset calibration voltage. 5. The imaging system defined in claim 4 , wherein the second calibration signal corresponds to a predetermined difference between a high gain signal voltage and a high gain reset voltage sampled at a light intensity level, and wherein the light intensity level corresponds to an onset of charge overflow from the photodiode. 6. The imaging system defined in claim 1 , wherein a gain select transistor is interposed between the floating diffusion node and the gain select storage node. 7. The imaging system defined in claim 6 , wherein the high gain configuration occurs when the gain select transistor is deactivated such that the floating diffusion node is isolated from the gain select storage node by the gain select transistor. 8. A method of operating an imaging system, comprising: with a photodiode in a dual gain pixel, accumulating charge in response to incident light; with readout circuitry, reading out a first signal while the pixel is in a high gain configuration, wherein the first signal is based on a first portion of the accumulated charge that overflows from the photodiode into a floating diffusion node and a gain select storage node; with a transfer transistor, transferring a second portion of the accumulated charge from the photodiode to the floating diffusion node in the high gain configuration; and with the readout circuitry, reading out a second signal while the pixel is in the high gain configuration, wherein the second signal is based on the first and second portions of the accumulated charge at the floating diffusion node; and in response to reading out the second signal, resetting the dual gain pixel to a pixel reset voltage. 9. The method defined in claim 8 , wherein the high gain configuration comprises deasserting a gate signal for a gain select transistor to isolate the floating diffusion node from the gain select storage region. 10. The method defined in claim 8 , further comprising: with image processing circuitry, receiving first and second signals from the readout circuitry and generating a high dynamic range signal based on the first and second signals. 11. The method defined in claim 10 , wherein the high dynamic range signal is generated based on the first and second signals and on first and second calibration signals. 12. The method defined in claim 11 , wherein the first calibration signal is a dark offset calibration signal. 13. The method defined in claim 12 , wherein the second calibration signal is based on a predetermined difference between a high gain signal voltage and a high gain reset voltage each sampled at a light intensity threshold, wherein the light intensity threshold corresponds to a light intensity level at which charge overflow begins to occur at the photodiode. 14. A method of operating an imaging system, comprising: with a photodiode in a pixel during an exposure period, accumulating charge in response to incident light, wherein a first portion of the accumulated charge overflows from the photodiode into a storage node during the exposure period in high light conditions, and wherein a second portion of the accumulated charge remains at the photodiode during the exposure period; with readout circuitry, reading out a first signal while the pixel is in a high gain configuration, wherein the first signal is based on the first portion of the accumulated charge; with the readout circuitry, reading out a second signal while the pixel is in the high gain configuration, wherein the second signal is based on the first and second portions of the accumulated charge; in response to reading out the second signal, resetting the pixel to a pixel reset voltage; and with image processing circuitry, generating a high dynamic range image signal, wherein the high dynamic range image signal is generated based on the first and second signals and a first calibration signal in a first range of light conditions, and wherein the high dynamic range image signal is generated based on the first and second signals, the first calibration signal, and a second calibration value in a second range of light conditions. 15. The method of claim 14 , wherein the first range of light conditions comprises low light conditions for which no portion of the accumulated charge overflows from the photodiode. 16. The method of claim 15 , wherein the second signal becomes clipped above a light intensity threshold, and wherein the second range of light conditions comprises a range of light intensity values that is adjacent to and greater than the light intensity threshold. 17. The method of claim 16 , wherein the first calibration signal is a dark offset calibration signal. 18. The method of claim 17 , wherein the second calibration signal is based on a predetermined difference between a high gain signal voltage and a high gain reset voltage each sampled at the light intensity threshold. 19. The method of claim 14 , wherein the high dynamic range image signal is additionally based on a predefined function, wherein the predefined function is a function of light intensity.