Fluidic dies

What is claimed is: 1. A fluidic die, comprising: at least two zones; a reference temperature sensor communicatively coupled to each zone to output a voltage representative of a temperature of all the zones; a calibration voltage generator coupled between the zones and the reference temperature sensor; and a calibration loop circuit associated with each zone to calibrate a zone temperature sensor of each zone based on output provided by the reference temperature sensor; wherein a respective calibration loop circuit is located in each zone. 2. The fluidic die of claim 1 , wherein the calibration loop circuit within each zone comprises: a summing amplifier to output a voltage representative of a voltage from a zone temperature sensor; a comparator to compare the voltage from the summing amplifier with the voltage provided by the reference temperature sensor; an offset counter to change state by a value based on a difference between the voltage provided by the reference temperature sensor and the voltage from the zone temperature sensor; and a digital-to-analog converter (DAC) to convert the output of the offset counter to an offset voltage and send the offset voltage to the summing amplifier, wherein, for a number of iterations: the summing amplifier sums the offset voltage with the voltage from the zone temperature sensor, the comparator compares the summed voltage with the voltage provided by the reference temperature sensor; and the offset counter changes state by the value based on the comparison between the summed voltage and the voltage provided by the reference temperature sensor. 3. The fluidic die of claim 2 , comprising a sample and hold device to sample the voltage provided by the reference temperature sensor and hold a value defining the voltage provided by the reference temperature sensor at a constant level for a period of time. 4. The fluidic die of claim 1 , wherein the at least two zones are equal to a number of primitives in the fluidic die. 5. The fluidic die of claim 1 , comprising non-volatile memory, the non-volatile memory storing calibration data provided by the calibration loop circuit. 6. The fluidic die of claim 1 , wherein the reference temperature sensor runs a full length of a group of primitives of the fluidic die to sense an average temperature of primitives within the group of primitives. 7. A method of calibrating zonal temperatures within a fluidic die comprising: transmitting a voltage that corresponds to a reference temperature from a reference temperature sensor to at least one zone of the fluidic die, the zone comprising a calibration loop circuit; resetting an offset counter within the calibration loop circuit; with a comparator of the calibration loop circuit, comparing a voltage from a summing amplifier of the calibration loop circuit with the voltage provided by the reference temperature sensor; iterating a comparison of an adjusted voltage from the summing amplifier with the voltage provided by the reference temperature sensor, the adjusted voltage comprising the voltage from the summing amplifier plus an offset voltage from the offset counter; and sending a voltage signal that represents a calibrated temperature sensed in that zone to control logic. 8. The method of claim 7 , wherein the at least one zone comprises a plurality of zones, each zone comprising a calibration loop circuit. 9. The method of claim 7 , wherein calibration of the zonal temperatures within the fluidic die is performed upon power-up of the die. 10. The method of claim 7 , wherein calibration of the zonal temperatures within the fluidic die is performed during a quiescent period of the fluidic die. 11. The method of claim 7 , wherein comparing the voltage from the summing amplifier with the voltage provided by the reference temperature sensor comprises: with the summing amplifier, outputting the voltage from the summing amplifier representative of a voltage from a zone temperature sensor; with the comparator, comparing the voltage from the summing amplifier with the voltage provided by the reference temperature sensor; with the offset counter, incrementing by a value based on a difference between the voltage provided by the reference temperature sensor and the voltage from the zone temperature sensor; and with a digital-to-analog converter (DAC), converting the output of the offset counter to an offset voltage and sending the offset voltage to the summing amplifier, wherein, for a number of iterations: the summing amplifier adjusts the voltage from the zone temperature sensor based on the offset voltage, and the comparator compares the summed voltage with the voltage provided by the reference temperature sensor. 12. The method of claim 11 , comprising, with a sample and hold device: sampling the voltage provided by the reference temperature sensor; and holding a value defining the voltage provided by the reference temperature sensor at a constant level for a period of time. 13. A fluidic die comprising: at least two zones within the fluidic die, wherein each zone comprises: at least one fluid chamber; at least one actuator located within the fluid chamber; at least one fluid passageway fluidically coupled to the fluid chamber; a summing amplifier to output a voltage representative of a voltage from a zone temperature sensor; a comparator to compare the voltage from the summing amplifier with a voltage provided by a reference temperature sensor; an offset counter to increment by a value based on a difference between the voltage provided by the reference temperature sensor and the voltage from the summing amplifier; a digital-to-analog converter (DAC) to convert the output of the offset counter to an offset voltage and sending the offset voltage to the summing amplifier, wherein, for a number of iterations: the summing amplifier is to adjust the voltage from the zone temperature sensor based on the offset voltage, and the comparator is to compare the adjusted voltage with the voltage provided by the reference temperature sensor. 14. The fluidic die of claim 13 , comprising: a reference temperature sensor to sense a reference temperature; a calibration voltage generator to generate a calibration voltage based on the sensed reference temperature, the calibration voltage defining the voltage provided by a reference temperature sensor; a sample and hold device to: sample the calibration voltage; hold a value defining the calibration voltage at a constant level for a period of time; and provide the calibration voltage to the comparator. 15. The fluidic die of claim 13 , wherein the summing amplifier sends a signal to control logic identifying that the zone is calibrated in response to a determination that the voltage from the summing amplifier is equal to the voltage provided by the reference temperature sensor within a threshold amount. 16. The fluidic die of claim 1 , wherein the reference temperature sensor comprises a whole fluidic die thermal sense resistor (TSR). 17. The fluidic die of claim 2 , further comprising a counter reset line connected to each counter in each calibration loop circuit. 18. The fluidic die of claim 1 , wherein each calibration loop circuit further comprises a decoupling buffer to control connection of each calibration loop circuit to an analog bus so that only one calibration loop circuit is communicating with the analog bus at a time. 19. The fluidic die of claim 5 , wherein the memory stores a calibration value for