Sensor signal offset compensation system for a CMM touch probe

The invention claimed is: 1. A touch probe circuit that outputs a signal that contributes to the determination of a touch trigger signal, in a touch probe for use in a coordinate measurement system, the touch probe circuit comprising: a displacement sensor configured to output a sensor signal that is responsive to displacement of stylus attached to the touch probe; an offset compensation controller portion configured to provide a varying offset compensation signal that is used to compensate for variation in a rest-state signal component output by the displacement sensor; a difference amplifier connected to input the offset compensation signal and the sensor signal and to amplify the difference between the input signals, and to output the amplified difference as an offset compensated displacement signal, wherein the offset compensated displacement signal is output to a trigger signal determination processing circuit to contribute to the determination of a touch trigger signal for the touch probe, and is also input to the offset compensation controller portion for use in adjusting the offset compensation signal; wherein, the offset compensation controller portion is configured to provide a feedback loop that inputs the offset compensated displacement signal and responds to that input to generate a low pass filtered offset compensation signal that is input to the difference amplifier to compensate an offset in the sensor signal due to the rest-state signal component. 2. The touch probe circuit of claim 1 , wherein: the touch probe circuit comprises an analog-to-digital converter (A/D converter) nominally operating at M bits of resolution; and the difference amplifier comprises an analog amplifier configured to output the offset compensated displacement signal to the A/D converter, which is configured to convert the offset compensated displacement signal into a corresponding digital offset compensated displacement signal that is output to the trigger signal determination processing circuit, and that is also input to the offset compensation controller portion for use in adjusting the offset compensation signal. 3. The touch probe circuit of claim 2 , wherein the offset compensation controller portion comprises a digital-to-analog converter (D/A converter) nominally operating at N bits of resolution; and the offset compensation controller portion comprises a digital circuit configured to input the digital offset compensated displacement signal and determine the value of a low pass filtered digital offset compensation signal that is input to the D/A converter, and the D/A converter is configured to convert the low pass filtered digital offset compensation signal into a corresponding analog offset compensation signal that is input to the difference amplifier. 4. The touch probe circuit of claim 3 , wherein N is at least 2 bits larger than M. 5. The touch probe circuit of claim 4 , wherein M is at least 12. 6. The touch probe circuit of claim 3 , wherein M is at least 14 and N is at least as large as M. 7. The touch probe circuit of claim 3 , wherein the offset compensation controller portion is configured to input the digital offset compensated displacement signal at a first sample rate and output the low pass filtered digital offset compensation signal at a second sample rate that is at least 10 times slower than the first sample rate. 8. The touch probe circuit of claim 7 , wherein the second sample rate is at least 100 times slower than the first sample rate. 9. The touch probe circuit of claim 7 , wherein the first sample rate is at least 50 KHz. 10. The touch probe circuit of claim 3 , wherein the offset compensation controller portion comprises: a digital low pass filter configuration that is configured to input the digital offset compensated displacement signal and output a low pass filter digital output signal; and a digital corrective feedback controller configured to input the low pass filter digital output signal and determine the value of the low pass filtered digital offset compensation signal that is input to the D/A converter. 11. The touch probe circuit of claim 10 , wherein the digital corrective feedback controller is configured to operate as proportional integrating controller responsive to changes in the low pass filter digital output signal. 12. The touch probe circuit of claim 1 , wherein the difference amplifier is configured to provide a relatively higher bandwidth having a first cutoff frequency, and the offset compensation controller portion is configured to generate the low pass filtered offset compensation signal corresponding to a relatively lower bandwidth having a second cutoff frequency, wherein the second cutoff frequency is at least 1000 times lower than the first cutoff frequency. 13. The touch probe circuit of claim 12 , wherein the second cutoff frequency is at least 5000 times lower than the first cutoff frequency. 14. The touch probe circuit of claim 12 , wherein the first cutoff frequency is at least 5000 Hz and the second cutoff frequency is at most 5 Hz. 15. The touch probe circuit of claim 14 , wherein the second cutoff frequency is at least 0.1 Hz. 16. The touch probe circuit of claim 12 , wherein the offset compensation controller portion comprises: a low pass filter configuration configured to input the offset compensated displacement signal and output a low pass filter output signal having the second cutoff frequency; and a corrective feedback controller configured to input the low pass filter output signal, and determine the level of the low pass filtered offset compensation signal that is generated and input to the difference amplifier. 17. The touch probe circuit of claim 16 , wherein the corrective feedback controller is configured to operate as proportional integrating controller responsive to changes in the low pass filter output signal. 18. The touch probe circuit of claim 12 , wherein: the touch probe circuit comprises an analog-to-digital converter (A/D converter) nominally operating at M bits of resolution; the difference amplifier comprises an analog amplifier configured to output the offset compensated displacement signal to the A/D converter, which is configured to convert the offset compensated displacement signal into a corresponding digital offset compensated displacement signal that is output to the trigger signal determination processing circuit, and that is also input to the offset compensation controller portion for use in adjusting the offset compensation signal; the offset compensation controller portion comprises a digital-to-analog converter (D/A converter) nominally operating at N bits of resolution; and the offset compensation controller portion comprises a digital circuit configured to input the digital offset compensated displacement signal and determine the value of a low pass filtered digital offset compensation signal that has the second cutoff frequency and that is input to the D/A converter, and the D/A converter is configured to convert the low pass filtered digital offset compensation signal into a corresponding analog low pass filtered offset compensation signal that has the second cutoff frequency and that is input to the difference amplifier. 19. The touch probe circuit of claim 1 , wherein: the offset compensation controller portion is further configured to hold the low pass filtered offset compensation signal that is input to the difference amplifier substantially constant during a time when the trigger signal determination processing circuit outp