Resonance frequency detector and sensing device

The invention claimed is: 1. A resonance frequency detector comprising: an adder that adds a correction term to an oscillation frequency of an output signal of an oscillator, and detects a predetermined resonance frequency of a resonance element, wherein the correction term is generated based on a phase error in a phase locked loop and a degree of change in phase at the predetermined resonance frequency, and the phase locked loop generates a control signal based on the phase error between an output signal of the resonance element that resonates at the predetermined resonance frequency and the output signal of the oscillator that varies the oscillation frequency according to the control signal. 2. The resonance frequency detector according to claim 1 , wherein an inclination of the phase is calculated by a Q value at the predetermined resonance frequency of the resonance element and the predetermined resonance frequency. 3. The resonance frequency detector according to claim 1 , wherein an inclination of the phase is detected on the basis of an actual measurement value of a degree of change in the phase at the predetermined resonance frequency of the resonance element. 4. The resonance frequency detector according to claim 1 , wherein the oscillation frequency of the output signal of the oscillator is detected on the basis of the control signal. 5. The resonance frequency detector according to claim 4 , further comprising: an oscillation frequency detector that detects the oscillation frequency of the output signal of the oscillator by multiplying the control signal by a predetermined frequency conversion coefficient. 6. The resonance frequency detector according to claim 1 , further comprising: a correction term generator that generates the correction term by multiplying a reciprocal of an inclination of the phase at the predetermined resonance frequency of the resonance element by the phase error. 7. The resonance frequency detector according to claim 6 , wherein the correction term generator generates the correction term by multiplying the reciprocal of the inclination of the phase at the predetermined resonance frequency of the resonance element by the phase error and a predetermined negative value. 8. The resonance frequency detector according to claim 1 , wherein the adder detects a digital signal representing the predetermined resonance frequency by adding a digital signal representing the correction term based on a digital signal representing the phase error and a digital signal representing an inclination of the phase at the predetermined resonance frequency of the resonance element to the oscillation frequency of a digital signal representing the output signal of the oscillator. 9. The resonance frequency detector according to claim 1 , wherein the resonance element is a micro electro mechanical systems (MEMS) resonance element. 10. A sensing device comprising: a resonance frequency detector; and a phase locked loop connected to the resonance frequency detector, wherein the resonance frequency detector includes an adder that adds a correction term to an oscillation frequency of an output signal of an oscillator, and detects a predetermined resonance frequency of a resonance element, wherein the correction term is generated based on a phase error in the phase locked loop and a degree of change in phase at the predetermined resonance frequency, and the phase locked loop generates a control signal based on the phase error between an output signal of the resonance element that resonates at the predetermined resonance frequency and the output signal of the oscillator that varies the oscillation frequency according to the control signal, and the phase locked loop comprises the oscillator, the resonance element that resonates at the predetermined resonance frequency and outputs a signal obtained by shifting a phase of the output signal of the oscillator by 90 degrees at the predetermined resonance frequency, a phase detector that detects the phase error between the output signal of the resonance element and the output signal of the oscillator, and a feedback controller that controls the oscillation frequency of the output signal of the oscillator by proportional control and integral control according to the phase error. 11. The sensing device according to claim 10 , wherein the phase detector comprises a multiplier that multiplies the output signal of the oscillator and the output signal of the resonance element, and a filter that detects, as the phase error, a low-frequency component signal included in a multiplication result of the multiplier. 12. The sensing device according to claim 10 , wherein the oscillator outputs a first oscillation signal, a second oscillation signal obtained by shifting a phase of the first oscillation signal by 90 degrees, and a third oscillation signal obtained by shifting a phase of the second oscillation signal by 90 degrees, the resonance element outputs a signal obtained by shifting the phase of the first oscillation signal by 90 degrees, and the phase detector comprises a multiplier that multiplies the second oscillation signal by the output signal of the resonance element and multiplies the third oscillation signal by the output signal of the resonance element, a filter that extracts a first signal of a low-frequency component included in a signal obtained by multiplying the second oscillation signal by the output signal of the resonance element and a second signal of a low-frequency component included in a signal obtained by multiplying the third oscillation signal by the output signal of the resonance element, and a phase difference calculator that calculates the phase error on the basis of the first signal and the second signal. 13. The sensing device according to claim 10 , further comprising: a physical quantity calculator that calculates a physical quantity on the basis of the predetermined resonance frequency detected by the adder. 14. The sensing device according to claim 10 , further comprising: a frequency error detector that detects a frequency error between the predetermined resonance frequency detected by the adder and a reference frequency when an acceleration is zero; and a physical quantity calculator that calculates the acceleration on the basis of the frequency error detected by the frequency error detector. 15. The sensing device according to claim 10 , further comprising: a frequency error detector that detects a frequency error between the predetermined resonance frequency detected by the adder and a reference frequency when a gas concentration is equal to or less than a predetermined concentration; and a physical quantity calculator that calculates the gas concentration on the basis of the frequency error detected by the frequency error detector. 16. The sensing device according to claim 10 , wherein the oscillator, the phase detector, the feedback controller, and the adder are digital circuits, the resonance element is an analog circuit, and the output signal of the oscillator, an output signal of the feedback controller, an output signal of the phase detector, and an output signal of the adder are digital signals. 17. The sensing device according to claim 16 , further comprising: a digital-to-analog (DA) converter that converts a first digital signal output from the oscillator into an analog oscillation signal to be input to the resonance element; and an analog-to-digital (AD) converter that converts the output signal of the resonance element into a