Current steering ramp compensation scheme and digital circuit implementation

What is claimed is: 1. A ramp generator, comprising: a plurality of switched current sources coupled in parallel between a resistor and ground, wherein an output of the ramp generator is coupled to a node between the resistor and the plurality of switched current sources; and a digital ramp control signal generator comprising a counter configured to generate a ramp control signal in response to a clock signal, wherein the ramp control signal comprises a plurality of bits, wherein each bit of the ramp control signal is coupled to control switching of a respective one of the plurality of switched current sources to generate a ramp signal at the output of the ramp generator, wherein the digital ramp control signal generator is coupled to receive a reset signal to zero the ramp control signal, wherein the digital ramp control signal generator is further coupled to receive a set bits signal to initialize the ramp signal to a preset value after every reset of the ramp control signal to add a DC offset compensation current determined by the preset value to the ramp signal. 2. The ramp generator of claim 1 , wherein the ramp control signal comprises M least significant bits (LSB s) and N most significant bits (MSB s), wherein the plurality of switched current sources comprises M LSB switched binary weighted current sources coupled to N MSB switched binary weighted current sources. 3. The ramp generator of claim 2 , wherein the digital ramp control signal generator comprises a ripple counter comprising a M+N flip flops. 4. The ramp generator of claim 3 , wherein each of the M+N flip flops of the ripple counter is coupled to receive the reset signal to zero the ramp control signal. 5. The ramp generator of claim 4 , wherein the M LSB flip flops of the ripple counter are coupled to receive the set bits signal to initialize the ramp control signal to the preset value after every reset of the ramp signal to add a DC offset compensation current to the ramp signal, wherein the N MSB flip flops of the ripple counter are not coupled to receive the set bits signal. 6. The ramp generator of claim 1 , further comprising a set bit control signal generator configured to generate the set bit signal in response to the clock signal, the reset signal, and a preset value signal. 7. The ramp generator of claim 6 , wherein the set bit control signal generator comprises: a flip flop having an input coupled to a logic high value, a clock input coupled to receive the clock signal, and a reset input coupled to receive the reset signal, wherein the flip flop is configured to generate a preset enable signal at an inverted output in response to the reset signal and the clock signal, wherein the preset enable signal is asserted for one clock cycle after the reset signal is de-asserted; and a logical AND circuit having a first input coupled to receive a preset value signal, a second input coupled to receive the preset enable signal from the flip flop, and an inverted input coupled to receive the reset signal, wherein the logical AND circuit is configured to generate the set bit signal. 8. The ramp generator of claim 7 , wherein the logical AND circuit comprises: a first AND gate having a first input coupled to receive the preset value, and a second input coupled to receive the preset enable signal from the flip flop; and a second AND gate having a first input coupled to an output of the first AND gate, and an inverted input coupled to receive the reset signal, wherein the second AND gate is configured to generate the set bit signal. 9. The ramp generator of claim 7 , wherein the logical AND circuit comprises: a NOR gate having a first input coupled to receive the preset value, and an inverted input coupled to receive the preset enable signal from the flip flop; and a NAND gate having a first input coupled to an output of the NOR gate, and an inverted input coupled to receive the reset signal, wherein the NAND gate is configured to generate the set bit signal. 10. The ramp generator of claim 1 , wherein the ramp signal is coupled to a comparator circuit of an analog to digital converter coupled to a plurality of bitlines of an imaging system. 11. The ramp generator of claim 10 , wherein the DC offset compensation current determined by the preset value added to the ramp signal is determined in response to a product of a frequency of the clock signal and a resistor capacitor (RC) time constant of a load coupled to the output of the ramp generator. 12. An imaging system, comprising: a pixel array including a plurality of pixel circuits configured to generate image signals in response to incident light; a control circuit coupled to the pixel array to control operation of the pixel array; and a readout circuit coupled to the pixel array to read out the image signals from the pixel array through a plurality of bitlines, wherein the readout circuit includes an analog to digital converter (ADC) including a comparator circuit coupled to the plurality of bitlines to receive the image signals, wherein the comparator circuit is further coupled to receive a ramp signal from a ramp generator, wherein the ramp generator comprises: a plurality of switched current sources coupled in parallel between a resistor and ground, wherein the ramp signal is configured to be generated at an output coupled to a node between the resistor and the plurality of switched current sources; and a digital ramp control signal generator comprising a counter configured to generate the ramp control signal in response to a clock signal, wherein the ramp control signal comprises a plurality of bits, wherein each bit of the ramp control signal is coupled to control switching of a respective one of the plurality of switched current sources to generate the ramp signal, wherein the digital ramp control signal generator is coupled to receive a reset signal to zero the ramp control signal, wherein the digital ramp control signal generator is further coupled to receive a set bits signal to initialize the ramp signal to a preset value after every reset of the ramp control signal to add a DC offset compensation current determined by the preset value to the ramp signal. 13. The imaging system of claim 12 , further comprising function logic coupled to the readout circuit to store digital representations of the image signals from the pixel array. 14. The imaging system of claim 12 , wherein the ramp control signal comprises M least significant bits (LSB s) and N most significant bits (MSB s), wherein the plurality of switched current sources comprises M LSB switched binary weighted current sources coupled to N MSB switched binary weighted current sources. 15. The imaging system of claim 14 , wherein the digital ramp control signal generator comprises a ripple counter comprising a M+N flip flops. 16. The imaging system of claim 15 , wherein each of the M+N flip flops of the ripple counter is coupled to receive the reset signal to zero the ramp control signal. 17. The imaging system of claim 16 , wherein the M LSB flip flops of the ripple counter are coupled to receive the set bits signal to initialize the ramp control signal to the preset value after every reset of the ramp signal to add a DC offset compensation current to the ramp signal, wherein the N MSB flip flops of the ripple counter are not coupled to receive the set bits signal. 18. The imaging system of claim 12 , further comprising a set bit control signal generator configured to generate the set bit signal in response to the clock signal, the reset signal, and a preset value signal.