Aging compensation of a ferroelectric piezoelectric shock sensor

What is claimed is: 1 . An apparatus comprising: a piezoelectric device; a temperature sensor; and a circuit coupled to the piezoelectric device, temperature sensor, and a memory, the circuit configurable to: receive a signal from the piezoelectric device; receive a measurement of a temperature of the piezoelectric device; read a first parameter from the memory, in which the first parameter relates the signal to an acceleration value; read a second parameter from the memory, in which the second parameter represents a degree of drift of the piezoelectric device at the temperature; and determine an acceleration of the piezoelectric device based on the signal, the first parameter and the second parameter. 2 . The apparatus of claim 1 , wherein the circuit is configurable to determine an acceleration of the piezoelectric device based on the signal, the first parameter, and the second parameter based on: determining a raw acceleration value based on the first parameter and the signal; and determining the acceleration by scaling the raw acceleration value with the second parameter. 3 . The apparatus of claim 1 , wherein the signal is a first signal, and the circuit is configurable to: receive a second signal from the piezoelectric device when the piezoelectric device is at a predetermined acceleration; determine the first parameter based on the second signal; and store the first parameter into the memory. 4 . The apparatus of claim 1 , wherein the signal is a first signal, the temperature is a first temperature, the apparatus further comprises a pyroelectric device and a heater coupled to the circuit, and the circuit is configurable to: control the heater to heat the pyroelectric device to a second temperature; receive a second signal from the pyroelectric device at the second temperature; measure the second temperature; determine the second parameter based on the second signal and the second temperature; and store the second parameter in the memory. 5 . The apparatus of claim 4 , wherein the heater includes a resistor, and the circuit is configurable to heat the pyroelectric device by applying a first voltage across the resistor, and measure the second temperature by measuring a second voltage across the resistor. 6 . The apparatus of claim 4 , wherein the circuit is configurable to pole the piezoelectric device before receiving the first signal, and pole the pyroelectric device before receiving the second signal. 7 . The apparatus of claim 6 , wherein: the piezoelectric device includes a set of serially-connected piezoelectric capacitors; the pyroelectric device includes a set of serially-connected pyroelectric capacitors; the apparatus further comprises first poling signal sources and second poling signal sources; and the circuit is configurable to: pole the piezoelectric device by successively connecting first poling signal sources to a respective one of the set of piezoelectric capacitors in a first sequence, and successively disconnecting the first poling signal sources from the respective one of the set of piezoelectric capacitors in a second sequence reversed from the first sequence; and pole the pyroelectric device by connecting second poling signal sources to a respective one of the set of pyroelectric capacitors in a third sequence, and successively disconnecting the second poling signal sources from the respective one of the set of pyroelectric capacitors in a fourth sequence reversed from the third sequence. 8 . The apparatus of claim 7 , wherein the first poling signal sources and the second poling signal sources are part of a sensor including the pyroelectric device and the piezoelectric device. 9 . The apparatus of claim 1 , further comprising a heater coupled to the circuit, and the circuit is configurable to heat the piezoelectric device to a second temperature, and determine the second parameter based on the second temperature. 10 . The apparatus of claim 1 , wherein the circuit is configured to pole the piezoelectric device before receiving the signal. 11 . A method comprising: receiving a signal from a piezoelectric device; receiving a measurement of a temperature of the piezoelectric device; reading a first parameter from a memory, in which the first parameter relates the signal to an acceleration value; reading a second parameter from the memory, in which the second parameter represents a degree of drift of the piezoelectric device at the temperature; and determining an acceleration of the piezoelectric device based on the signal, the first parameter, and the second parameter. 12 . The method of claim 11 , wherein determining an acceleration of the piezoelectric device based on the signal, the first parameter, and the second parameter includes: determining a raw acceleration value based on the first parameter and the signal; and determining the acceleration by scaling the raw acceleration value with the second parameter. 13 . The method of claim 11 , wherein the signal is a first signal, and the method further comprises: receiving a second signal from the piezoelectric device when the piezoelectric device is at a predetermined acceleration; determining the first parameter based on the second signal; and storing the first parameter into the memory. 14 . The method of claim 11 , wherein the signal is a first signal, the temperature is a first temperature, and the method further comprises: heating a pyroelectric device to a second temperature; receiving a second signal from the pyroelectric device at the second temperature; measuring the second temperature; determining the second parameter based on the second signal and the second temperature; and storing the second parameter in the memory. 15 . The method of claim 14 , wherein the pyroelectric device is heated by applying a first voltage across a resistor; and wherein the second temperature is measured by measuring a second voltage across the resistor. 16 . The method of claim 14 , further comprising poling the piezoelectric device before receiving the first signal, and poling the pyroelectric device before receiving the second signal. 17 . The method of claim 16 , wherein: the piezoelectric device includes a set of serially-connected piezoelectric capacitors; the pyroelectric device includes a set of serially-connected pyroelectric capacitors; the poling of the piezoelectric device includes successively connecting first poling signal sources to a respective one of the set of piezoelectric capacitors in a first sequence, and successively disconnecting the first poling signal sources from the respective one of the set of piezoelectric capacitors in a second sequence reversed from the first sequence; and the poling of the pyroelectric device includes successively connecting second poling signal sources to a respective one of the set of pyroelectric capacitors in a third sequence, and successively disconnecting the second poling signal sources from the respective one of the set of pyroelectric capacitors in a fourth sequence reversed from the third sequence. 18 . The method of claim 17 , wherein the first poling signal sources and the second poling signal sources are part of a sensor including the pyroelectric device and the piezoelectric device. 19 . The method of claim 11 , further comprising heating the piezoelectric device to a second temperature, and determining the second parameter based on the second temperature. 20 . The method of claim