Drive circuit, physical quantity sensor, and electronic device

The invention claimed is: 1. A drive circuit configured to drive an oscillator to vibrate the oscillator, the oscillator outputting a monitor signal according to a physical quantity, the drive circuit comprising: a drive signal generating unit that generates a drive signal having a drive frequency; a phase difference detector that detects a phase difference between the monitor signal and the drive signal; a frequency controller that controls the drive frequency based on the phase difference; an automatic gain control (AGC) unit that controls an amplitude of the drive signal according to an amplitude of the monitor signal; and an output unit that outputs the drive signal having the controlled amplitude to the oscillator, wherein the phase difference detector obtains the phase difference Pd based on a time difference Tdm between the drive signal and the monitor signal and a period Tdrv of the drive signal according to a following formula: Pd = Tdm Tdrv . 2. The drive circuit according to claim 1 , wherein the oscillator has a resonance frequency; and the frequency controller detects a difference between the drive frequency and the resonance frequency based on the phase difference so as to control the drive frequency. 3. The drive circuit according to claim 1 , wherein the output unit outputs a sine wave signal having a predetermined frequency and a predetermined amplitude to the oscillator when starting the oscillator. 4. The drive circuit according to claim 1 , wherein, when the oscillator outputs a current of the monitor signal, the drive circuit detects an amplitude of the monitor signal and is switched to control the drive signal by the AGC unit. 5. The drive circuit according to claim 1 , wherein the drive signal crosses a center value of the drive signal at a first zero-crossing point in a predetermined direction out of a rising direction and a falling direction, and crosses the center value of the drive signal at a second zero-crossing point subsequent to the first zero-crossing point in the predetermined direction, and the phase difference detector is configured to: sample the drive signal at a first sampling point immediately subsequent to the first zero-crossing point with a sampling clock; sample the drive signal at a second sampling point immediately before the second zero-crossing point with the sampling clock; and calculate the period Tdrv of the drive signal with a first fractional part Fr1 which is a duration from the first zero-crossing point to the first sampling point, a first integer part In1 which is a duration from the first sampling point to the second sampling point, and a second fractional part Fr2 which is a duration from the second sampling point to the second zero-crossing point according to a following formula: Tdrv=Fr 1+ In 1+ Fr 2. 6. The drive circuit according to claim 5 , wherein the monitor signal crosses a center value of the monitor signal at a third zero-crossing point subsequent to the first sampling point in the predetermined direction; and the phase difference detector is configured to: sample the monitor signal from the first sampling point to a third sampling point immediately before the third zero-crossing point with the sampling clock; and calculate a time difference Tdm between the drive signal and the monitor signal with a second integer part In2 corresponding to a duration from the first sampling point to the third sampling point and a third fractional part Fr3 corresponding to a duration from the third sampling point to the third zero-crossing point according to a following formula: Tdm=Fr 1+ In 2+ Fr 3. 7. The drive circuit according to claim 1 , wherein the phase difference detector starts detecting the phase difference after a predetermined duration elapses after starting of the oscillator. 8. The drive circuit according to claim 1 , wherein the frequency controller controls the drive frequency by a proportional-derivative (PD) control at a steady state of the oscillator. 9. The drive circuit according to claim 1 , wherein the drive circuit includes: a first amplifier; a second amplifier; a first transistor connected to an output port of the first amplifier; a second transistor connected to an output port of the second amplifier; a first current amplifier connected to an output port of the first transistor and an output port of the second transistor; and a first current source connected between the first transistor and the first current amplifier. 10. The drive circuit according to claim 9 , wherein the drive circuit further includes: a third transistor connected to an output port of the first amplifier; a third amplifier; a fourth transistor connected to an output port of the third amplifier; a second current amplifier connected to an output port of the third transistor and an output port of the fourth transistor; and a second current source connected between the third transistor and the second current amplifier. 11. The drive circuit according to claim 10 , wherein the drive circuit further includes a push-pull controlled output circuit connected to the second current amplifier, and the third amplifier includes a first input port and a second input port, the first input port being connected to a limited range of set values, the second input port having the output circuit input thereto. 12. The drive circuit according to claim 9 , wherein the drive circuit further includes a push-pull controlled output circuit connected to the first current amplifier, and the second amplifier includes a first input port and a second input port, the first input port being connected to a limited range of set values, the second input port having the output circuit input thereto. 13. A drive circuit configured to drive an oscillator to vibrate the oscillator, the oscillator outputting a monitor signal according to a physical quantity, the drive circuit comprising: a drive signal generating unit that generates a drive signal having a drive frequency; a phase difference detector that detects a phase difference between the monitor signal and the drive signal; a frequency controller that controls the drive frequency based on the phase difference; an automatic gain control (AGC) unit that controls an amplitude of the drive signal according to an amplitude of the monitor signal; and an output unit that outputs the drive signal having the controlled amplitude to the oscillator, wherein the drive circuit includes: a first input port; a second input port; a first transistor connected to an output port of the first input port; a second transistor connected to an output port of the second input port; a first current amplifier connected to an output port of the first transistor and an output port of the second transistor; and a first current source connected between the first transistor and the first current amplifier. 14. The drive circuit according to claim 13 , wherein the output port of the first transistor is connected to a primary side of the first current amplifier. 15. The drive circuit according to claim 13 , wherein the first current source is connected to a first potential, and the first transistor, the second transistor, and the first current amplifier are connected to a second potential higher than the first potential.