Steering-wheel grip sensor and grip detection method

The invention claimed is: 1. A steering-wheel grip sensor, comprising: a driven electrode having a planar shape and extending along a rim of a steering wheel; a sensor electrode having a planar shape and opposed to the driven electrode; a sine-wave generator that supplies a sinusoidal voltage to the driven electrode; a charge amplifier that includes a feedback capacitive element, detects a change in an amount of charge generated according to capacitance of the sensor electrode, and outputs the change in the amount of charge as a change in a voltage; a multiplication processor that multiplies the sinusoidal voltage by an output voltage from the charge amplifier; an integrator that smooths, by integration, a result of multiplication by the multiplication processor; and a grip determiner that determines whether the steering wheel is gripped, according to a level of the result smoothed, wherein the sine-wave generator receives a rectangular-wave signal, and generates the sinusoidal voltage in synchronization with the rectangular-wave signal, and the steering-wheel grip sensor further comprises: a memory; a first analog-to-digital (AD) converter that performs AD conversion on the output voltage from the charge amplifier in synchronization with the rectangular-wave signal, and stores a result of the AD conversion into the memory as first digital data; and a second AD converter that performs AD conversion on the sinusoidal voltage from the sine-wave generator in synchronization with the rectangular-wave signal, and stores a result of the AD conversion into the memory as second digital data. 2. The steering-wheel grip sensor according to claim 1 , wherein the charge amplifier includes: a first input terminal that receives the sinusoidal voltage; a second input terminal connected to the sensor electrode; an output terminal; the feedback capacitive element connected between the output terminal and the second input terminal; and an operational amplifier connected to the first input terminal, the second input terminal, and the output terminal, and the charge amplifier supplies the sinusoidal voltage output through the output terminal to the sensor electrode via the feedback capacitive element. 3. The steering-wheel grip sensor according to claim 1 , wherein the charge amplifier includes a low-pass filter connected in parallel to the feedback capacitive element, and the low-pass filter passes a signal having a frequency lower than a frequency of the sinusoidal voltage. 4. The steering-wheel grip sensor according to claim 1 , wherein the multiplication processor performs processing for averaging each of a waveform indicated by the first digital data and a waveform indicated by the second digital data, and multiplies an average of the first digital data by an average of the second digital data. 5. The steering-wheel grip sensor according to claim 1 , wherein the multiplication processor multiplies the first digital data by the second digital data, and performs processing for averaging a waveform indicated by digital data resulting from multiplying the first digital data by the second digital data. 6. The steering-wheel grip sensor according to claim 4 , wherein the rectangular-wave signal is switched to one of at least three frequencies, and the first AD converter and the second AD converter store, for each of the at least three frequencies, the first digital data and the second digital data into the memory, respectively. 7. The steering-wheel grip sensor according to claim 4 , wherein the first AD converter and the second AD converter generate the first digital data and the second digital data, respectively, the first digital data and the second digital data each corresponding to at least two cycles of a waveform of the sinusoidal voltage. 8. The steering-wheel grip sensor according to claim 4 , wherein the first AD converter and the second AD converter generate the first digital data and the second digital data, respectively, the first digital data and the second digital data each corresponding to at least three cycles of a waveform of the sinusoidal voltage, and the multiplication processor compares portions of the first digital data corresponding to different ones of the at least three cycles of the waveform, and discards one of the portions of the first digital data having a most distant value. 9. The steering-wheel grip sensor according to claim 4 , wherein the first AD converter and the second AD converter generate the first digital data and the second digital data, respectively, the first digital data and the second digital data each corresponding to at least three cycles of a waveform of the sinusoidal voltage, and the multiplication processor calculates, for each cycle of the at least three cycles of the waveform, an average and a deviation of a portion of the first digital data corresponding to the cycle, and discards the portion of the first digital data corresponding to the cycle when the deviation is greater than or equal to a threshold. 10. The steering-wheel grip sensor according to claim 9 , wherein the multiplication processor changes a frequency of the rectangular-wave signal when a predetermined number of cycles for which the deviation is greater than or equal to the threshold are in a continuous series. 11. The steering-wheel grip sensor according to claim 1 , further comprising: a monitor that monitors whether a failure has occurred; and an attenuation switch that attenuates or amplifies the sinusoidal voltage, wherein the monitor has an ordinary monitor mode in which the attenuation switch does not attenuate or amplify the sinusoidal voltage and a temporary monitor mode in which the attenuation switch attenuates or amplifies the sinusoidal voltage, in the ordinary monitor mode, the monitor monitors whether at least one of a ground fault of the driven electrode or a ground fault of the sensor electrode has occurred, and in the temporary monitor mode, the monitor monitors whether at least one of a breakage of the driven electrode, a breakage of the sensor electrode, or a short circuit between the driven electrode and the sensor electrode has occurred. 12. The steering-wheel grip sensor according to claim 11 , wherein the monitor controls an attenuation factor and an amplification factor of the attenuation switch. 13. The steering-wheel grip sensor according to claim 1 , further comprising: a corrector that performs correction processing for reducing a variation in an amount of charge generated in the sensor electrode, the variation being caused by an environmental change, wherein the multiplication processor further: shifts a phase of the output voltage from the charge amplifier by 90 degrees; multiplies the sinusoidal voltage by the output voltage shifted; and outputs, as an index of the environmental change, a result of multiplying the sinusoidal voltage by the output voltage shifted to the corrector. 14. The steering-wheel grip sensor according to claim 1 , further comprising: an other charge amplifier that includes a second feedback capacitive element, detects a change in an amount of charge generated in the driven electrode, and outputs the change in the amount of charge generated in the driven electrode as a second change in a second voltage, the change in the amount of charge generated in the driven electrode being caused by an environmental change; and a corrector that performs correction processing for reducing a variation in the amount of charge generated in the driven electrode, the variation being caused by the environmental change, wherein the m