Multiple resolution temperature sensor

What is claimed is: 1. An apparatus, comprising: a sigma delta modulator (SDM) analog-to-digital convertor (ADC) configured to receive an analog signal and to output each bit of a digital code for the analog signal to a different data line of a plurality of data lines, the SDM ADC configured to update the digital code on the plurality of data lines in accordance with a clock signal; a plurality of storage units, each storage unit coupled to data lines of the plurality of data lines that provide “r” least significant bits of the digital code, wherein “r” is a different number for at least two of the plurality of storage units; and control logic configured to instruct respective storage units of the plurality of storage units to sample “r” of the data lines to which the respective storage unit is coupled 2^r clock cycles after the SDM ADC first puts an initial value for the digital code onto the plurality of data lines. 2. The apparatus of claim 1 , wherein the SDM ADC further comprises a comparator configured to output a comparison signal each cycle of the clock signal based on the analog signal, the digital code that each respective storage unit stores being based on values for the comparison signal for 2^r clock cycles, wherein “r” is a resolution of the digital code for the respective storage unit. 3. The apparatus of claim 1 , wherein the SDM ADC further comprises a comparator configured to output a comparison signal each cycle of the clock signal based on the analog signal, the control logic comprising a counter configured to output the digital code on the plurality of data lines based on values for the comparison signal for a group of clock cycles. 4. The apparatus of claim 1 , wherein the SDM ADC further comprises: a fully differential amplifier having a first output and a second output, the SDM ADC configured to perform a first integration each clock cycle based on the analog signal and a first value at the first output and to perform a second integration each clock cycle based on a reference signal and a second value at the second output; a comparator configured output a comparison of the first value with the second value each clock cycle; and control logic configured to update the digital code each clock cycle based on the comparator output for a present clock cycle and previous clock cycles. 5. The apparatus of claim 1 , wherein the sigma delta modulator is a first order sigma delta modulator. 6. The apparatus of claim 5 , wherein the sigma delta modulator is a single bit sigma delta modulator. 7. The apparatus of claim 1 , wherein the sigma delta modulator is a single bit sigma delta modulator. 8. The apparatus of claim 1 , further comprising: a reference voltage generator configured to generate a proportional to temperature voltage, wherein the analog signal is the proportional to temperature voltage. 9. The apparatus of claim 1 , further comprising: a three-dimensional memory array of non-volatile storage elements, the control logic configured to perform on operation on the non-volatile storage elements based on the digital code from one or more of the plurality of storage units. 10. A method comprising: inputting an analog signal into a sigma delta modulator (SDM) analog-to-digital convertor (ADC); outputting an initial value for a digital code for the analog signal, by the SDM ADC, onto a data bus during a first clock cycle; outputting an updated digital code for the analog signal, by the SDM ADC, onto the data bus for each clock cycle after the first clock cycle; instructing, by control logic, a first storage unit to sample “n” bits of the digital code that are on the data bus “2^n−1” clock cycles after the first clock cycle; and instructing, by the control logic, a second storage unit to sample “m” bits of the digital code that are on the data bus “2^m−1” clock cycles after the first clock cycle, wherein “m” is greater than “n”. 11. The method of claim 10 , wherein outputting the updated digital code, by the SDM ADC, onto the data bus for each clock cycle after the first clock cycle comprises: performing, by the SDM ADC, a comparison each clock cycle based on the analog signal; and determining, by the SDM ADC, the updated digital code based on results of the comparison for the first clock cycle and results of the comparison for each following clock cycle. 12. The method of claim 11 , wherein performing the comparison each clock cycle based on the analog signal comprises: sampling the analog signal by the SDM ADC; and integrating, by the SDM ADC, based on the sampled analog signal and a previous output of the SDM ADC. 13. The method of claim 10 , wherein outputting the updated digital code, by the SDM ADC, onto the data bus for each clock cycle after the first clock cycle comprises: counting a number of ones output by the SDM ADC from the first clock cycle to a present clock cycle. 14. The method of claim 10 , wherein the analog signal comprises a proportional to absolute temperature signal, wherein the digital code is a temperature code. 15. An apparatus, comprising: a reference voltage generator configured to generate a bandgap voltage and a proportional to temperature voltage; a single-bit, first-order sigma delta modulator (SDM) analog-to-digital convertor (ADC) coupled to the reference voltage generator; a bus having data lines coupled to the SDM ADC, wherein the SDM ADC is configured to output a digital code having a least significant bit and a most significant bit onto the data lines, wherein the digital code is based on the bandgap voltage and the proportional to temperature voltage, the SDM ADC configured to update the digital code each cycle of a clock signal; a first storage unit coupled to “n” of the data lines that provide the “n” least significant bits of the digital code; a second storage unit coupled to “m” of the data lines that provide the “m” least significant bits of the digital code, wherein “m” is greater than “n”; and control logic configured to instruct the first storage unit to sample the “n” data lines that provide the “n” least significant bits of the digital code 2^n clock cycles after the SDM ADC first outputs an initial value of the digital code onto the bus and to instruct the second storage unit to sample the “m” data lines that provide the “m” least significant bits of the digital code 2^m clock cycles after the SDM ADC first outputs the initial value of the digital code onto the bus. 16. The apparatus of claim 15 , wherein the SDM ADC further comprises a comparator configured to output a comparison signal each cycle of the clock signal based on the bandgap voltage and the proportional to temperature voltage, the digital code that the first storage unit stores being based on values for the comparison signal for 2^n consecutive clock cycles, the digital code that the second storage unit stores being based on values for the comparison signal for 2^m consecutive clock cycles. 17. The apparatus of claim 15 , wherein the SDM ADC further comprises a comparator configured to output a comparison signal each cycle of the clock signal based on the bandgap voltage and the proportional to temperature voltage, the control logic comprising a counter configured to output the digital code on the data lines based on values for the comparison signal for a group of consecutive clock cycles. 18. The apparatus of claim 15 , wherein the SDM ADC is configured to, for each cycle of the clock signal: sample the bandgap voltage and the proportional to temperature voltage; and integrate based on the sample