Multi-stage overload protection scheme for pipeline analog-to-digital converters

What is claimed is: 1. An apparatus, comprising: a series of analog-to-digital converter (ADC) stages, wherein an input of a first ADC stage of the series of ADC stages is coupled to an input signal and wherein the first ADC stage is configured to: compare a voltage level of the input signal to one or more conversion threshold levels to generate a result in response to a transition of a clock signal; generate an output signal of the first ADC stage based on a value of the result; and in response to an assertion of a first reset signal, set a voltage level of the output signal to a particular voltage level; and a particular comparison circuit coupled to the first ADC stage of the series of ADC stages, wherein the particular comparison circuit is configured to assert the first reset signal in response to a determination that the voltage level of the input signal is outside of a first operating range defined by a first upper overload threshold level and a first lower overload threshold level; wherein an input of a second ADC stage of the series of ADC stages is coupled to the output signal of the first ADC stage and an output signal of the second ADC stage is coupled to an input of a third ADC stage; and a second comparison circuit coupled to the input of the third ADC stage, wherein the second comparison circuit is configured to assert a second reset signal based on the voltage level of the input signal in response to a determination that the voltage level of the output signal of the second stage is outside of a second operating range defined by a second upper overload threshold level, different than the first upper overload threshold level and a second lower overload threshold level different than the first lower overload threshold level. 2. The apparatus of claim 1 , wherein the particular comparison circuit is further configured to set the first upper overload threshold level to a voltage level that is greater than a maximum allowable voltage level of the first ADC stage, and to set the first lower overload threshold level to a voltage level that is less than a minimum allowable voltage level of the first ADC stage. 3. The apparatus of claim 2 , wherein the second comparison circuit is further configured to set the second upper overload threshold level to a voltage level that is less than a maximum allowable voltage level of the third ADC stage, and to set the second lower overload threshold level to a voltage level that is greater than a minimum allowable voltage level of the third ADC stage. 4. The apparatus of claim 1 , wherein a respective input of each ADC stage of a proper subset of the series of ADC stages is coupled to a respective comparison circuit. 5. The apparatus of claim 4 , wherein at least one comparison circuit coupled to at least one ADC stage of the proper subset is configured to assert a respective reset signal in response to a determination that a voltage level of its respective input is outside of the first operating range. 6. The apparatus of claim 5 , wherein remaining comparison circuits coupled to respective remaining ADC stages of the proper subset are configured to assert a respective reset signal in response to a determination that a voltage level of their respective inputs is outside of the second operating range. 7. The apparatus of claim 1 , further comprising: a synchronization circuit configured to assert a second reset signal, coupled to the second ADC stage of the series of ADC stages in response to another transition of the clock signal and in response to the assertion of the first reset signal. 8. A method for operating an analog-to-digital converter (ADC), the method comprising: comparing, by a first ADC stage of a series of ADC stages, a voltage level of an input signal to one or more conversion threshold levels to generate a result in response to particular transitions of a clock signal; in response to a first transition of the clock signal, generating an output signal of the first ADC stage based on the result; asserting, by a first comparison circuit coupled to the first ADC stage, a first reset signal in response to determining that the voltage level of the input signal exceeds an first allowable range of voltage levels; in response to the assertion of the first reset signal, setting, by the first ADC stage, a voltage level of the output signal to a particular voltage level; comparing, by a second ADC stage of the series of ADC stages, a voltage level of the output signal of the first ADC stage in response to a second transition of the clock signal, occurring after the first transition; and asserting, by a second comparison circuit coupled to the second ADC stage, a second reset signal in response to determining that the voltage level of the output signal of the first ADC stage exceeds a second allowable range of voltage levels, wherein the first allowable range and the second allowable range are different. 9. The method of claim 8 , wherein each ADC stage of a proper subset of the series of ADC stages is coupled to a respective comparison circuit. 10. The method of claim 8 , wherein the first allowable range of voltage levels includes voltage levels less than or equal to a first upper overload threshold level and greater than or equal to a first lower overload threshold level, and wherein the first upper overload threshold level is based on a maximum allowable voltage level of the first ADC stage and the first lower overload threshold level is based on a minimum allowable voltage level of the first ADC stage. 11. The method of claim 10 , wherein the second allowable range of voltage levels includes voltage levels less than or equal to a second upper overload threshold level and greater than or equal to a second lower overload threshold level, wherein the first upper overload threshold level is different than the second upper overload threshold level and the first lower overload threshold level is different than the second lower overload threshold level. 12. The method of claim 8 , further comprising comparing, by a third ADC stage of the series of ADC stages, a voltage level of the output signal of the second ADC stage in response to a third transition of the clock signal, occurring after the second transition. 13. The method of claim 12 , further comprising asserting a third reset signal, in response to third transition of the clock signal, and in response to asserting the second reset signal. 14. A system comprising: a circuit configured to generate an analog signal, wherein a voltage level of the analog signal varies over time; a clock source configured to generate a clock signal; and an analog to digital converter (ADC) including a series of ADC stages and a plurality of comparison circuits, wherein the ADC is configured to: compare a voltage level of the analog signal to one or more conversion threshold levels to generate a result using a first ADC stage of the series of ADC stages in response to a transition of the clock signal; generate an output signal of the first ADC stage based on the result; using a particular comparison circuit of the plurality of comparison circuits, assert a first reset signal in response to a determination that the voltage level of the analog signal is outside of a first operating range defined by a first upper overload threshold level and a first lower overload threshold level; and in response to the assertion of the first reset signal, set a voltage level of the output signal of the first ADC stage to a particular voltage level; wherein an input of a second ADC stage of the series of ADC stages is coupled to the output signal of the first ADC stag