JP2669396B2 - Microcomputer controlled piezoelectric oscillator - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a microcomputer-controlled piezoelectric oscillator for controlling a control voltage applied to a voltage-controlled piezoelectric oscillator by a microcomputer circuit according to the ambient temperature of the voltage-controlled piezoelectric oscillator, and more particularly to an ambient temperature. The present invention relates to a microcomputer controlled piezoelectric oscillator capable of obtaining a more stable output frequency with respect to a change in.

[0002]

2. Description of the Related Art Conventionally, in this type of microcomputer-controlled piezoelectric oscillator, as shown in FIG. 2, a voltage-controlled piezoelectric oscillator 1, a temperature sensor 3, an analog / digital converter 4, a digital / analog converter 6, A one-way data memory 7 and a microcomputer circuit 8 are provided.

In the voltage-controlled piezoelectric oscillator 1, the oscillation frequency changes according to the control voltage applied and supplied from the digital / analog converter 6. The temperature sensor 3 is arranged in the vicinity of the voltage controlled piezoelectric oscillator 1 and outputs an analog voltage according to the ambient temperature. The analog / digital converter 4 inputs the analog voltage from the temperature sensor 3, converts it into a digital code according to the ambient temperature, and outputs it to the microcomputer circuit 8. The digital / analog converter 6 converts the temperature-compensated data of the digital code input from the microcomputer circuit 8 into an analog voltage and supplies the analog voltage to the voltage-controlled piezoelectric oscillator 1.

The one-way data memory 7 is temperature-compensated based on one of the ambient temperature-output frequency characteristic of the voltage-controlled piezoelectric oscillator 1 as shown in FIG. A program for seeking data is stored.

Further, the microcomputer circuit 8 inputs a digital code corresponding to the ambient temperature from the analog / digital converter 4 and, according to the digital code, reads out from the one-way data memory circuit 7 by means of a program 1
One temperature compensation data is calculated, and the temperature compensation data by the digital code of the calculation result is output to the digital / analog converter 6.

With this configuration, when the ambient temperature of the voltage-controlled piezoelectric oscillator 1 detected by the temperature sensor 3 changes, the output frequency of the voltage-controlled piezoelectric oscillator 1 changes. The control voltage supplied from the analog converter 6 to the voltage-controlled piezoelectric oscillator 1 is changed to compensate.

[0007]

Generally, in a voltage-controlled piezoelectric oscillator used in a microcomputer-controlled piezoelectric oscillator, as shown in FIG. 3, the ambient temperature-oscillation frequency characteristics are such that the temperature rises and the temperature falls. And has a hysteresis of

In the above-mentioned conventional microcomputer controlled piezoelectric oscillator, the microcomputer circuit calculates the temperature compensation data by the program of the one-way data memory circuit, so that the temperature compensation data corresponding to the control voltage applied to the voltage controlled piezoelectric oscillator is obtained. Can be obtained only from the change due to the ambient temperature-oscillation frequency characteristic when the temperature rises or when the temperature falls. For this reason, there is a problem that an error occurs either when the ambient temperature rises or when the ambient temperature falls.

There is also a problem that an error is unavoidable even if the data in the memory circuit is an intermediate value when rising and falling.

An object of the present invention is to provide a microcomputer-controlled piezoelectric oscillator capable of obtaining a more stable output frequency with respect to changes in ambient temperature.

[0011]

A microcomputer-controlled piezoelectric oscillator according to the present invention is a microcomputer-controlled piezoelectric oscillator for controlling a control voltage applied to a voltage-controlled piezoelectric oscillator according to the ambient temperature of the voltage-controlled piezoelectric oscillator. A microcomputer circuit is provided for controlling the control voltage applied to the voltage controlled piezoelectric oscillator in consideration of the ambient temperature-oscillation frequency characteristic of the voltage controlled piezoelectric oscillator according to the changing direction of the rise and fall of the ambient temperature.

Further, as one specific means, the microcomputer-controlled piezoelectric oscillator includes a memory circuit for preliminarily storing temperature compensation data when the temperature of the voltage-controlled piezoelectric oscillator rises and when the temperature falls, and an ambient temperature. Temperature sensor which outputs an analog voltage according to the above, an analog / digital converter which inputs the analog voltage and converts it into a digital code, and an analog which inputs temperature compensation data by the digital code output from the microcomputer circuit. A digital / analog converter that converts the voltage into a voltage-controlled piezoelectric oscillator and applies the voltage to the voltage-controlled piezoelectric oscillator and a recent digital code input from the analog / digital converter are stored, and the ambient temperature of the ambient temperature is stored based on the stored digital code. Judge whether the direction of change is ascending or descending. And cooperates with a memory circuit, and a microcomputer circuit which obtains and outputs a temperature compensation data of said control voltage based on said change direction.

[0013]

Next, the present invention will be described with reference to the drawings.

FIG. 1 is a functional block diagram showing an embodiment of the present invention. In the microcomputer-controlled piezoelectric oscillator shown in FIG. 1, a voltage-controlled piezoelectric oscillator 1, a bidirectional data memory circuit 2, a temperature sensor 3, an analog / digital converter 4, a microcomputer circuit 5, and a digital / analog converter are provided. 6 is provided, and the bidirectional data memory circuit 2 and the microcomputer circuit 5 are different from the conventional example shown in FIG.

In the voltage-controlled piezoelectric oscillator 1, the oscillation frequency changes according to the control voltage applied and supplied from the digital / analog converter 6. The temperature sensor 3 is arranged in the vicinity of the voltage controlled piezoelectric oscillator 1 and outputs an analog voltage according to the ambient temperature. The analog / digital converter 4 inputs the analog voltage from the temperature sensor 3, converts it into a digital code corresponding to the ambient temperature, and outputs it to the microcomputer circuit 5. The digital / analog converter 6 converts the temperature compensation data of the digital code input from the microcomputer circuit 5 into an analog voltage and supplies the analog voltage to the voltage controlled piezoelectric oscillator 1.

The bidirectional data memory circuit 2 stores a program for obtaining temperature compensation data based on changes in the ambient temperature versus output frequency characteristic of the voltage controlled piezoelectric oscillator 1 when the temperature rises and when the temperature falls. In this program, temperature compensation data is obtained from a digital code corresponding to the ambient temperature output from the analog / digital converter 4. That is, it is assumed that the bidirectional data memory circuit 2 stores in advance an arithmetic program based on the temperature rising compensation data calculation formula U (t) and the temperature falling compensation data calculation formula D (t).

Further, the microcomputer circuit 5 inputs the digital code corresponding to the ambient temperature from the analog / digital converter 4 and stores the last two data, and based on the change of the data of the digital code, the ambient temperature is changed. The temperature compensation data is calculated by the program read from the bidirectional data memory circuit 2 after judging whether the temperature rises or falls, and the temperature compensation data of the calculation result by this digital code is output to the digital / analog converter 6. ing.

Next, the temperature compensation operation will be described.

First, the microcomputer circuit 5 generates the temperature compensation data C (t) at the ambient temperature data t = t0.
0) is output and the voltage applied to the voltage controlled piezoelectric oscillator 1 is controlled to be constant.

From this state, when the ambient temperature rises and changes to ambient temperature data t = (t0 + Δt), the microcomputer circuit 5 judges the ambient temperature rise from the ambient temperature data difference (+ Δt), and The temperature rise compensation data calculation formula U (t) is read from the temperature data memory circuit 2 and the temperature rise compensation data calculation formula U (t0 + Δt) is used to calculate the temperature compensation data C (t0 + Δt). On the other hand, when the ambient temperature drops, the microcomputer circuit 5
A temperature drop is determined from the ambient temperature data difference (-Δt), and a temperature drop compensation data calculation formula D (t) is read from the bidirectional data memory circuit 2, and a temperature drop compensation data calculation formula D (t0-Δt) ) Using the temperature compensation data C (t0
−Δt) is calculated.

The calculated temperature compensation data C (t1
) Is converted into an analog voltage by the digital / analog converter 6 and supplied to the voltage controlled piezoelectric oscillator 1 and applied. As a result, the applied analog voltage changes by the amount of change due to "Δt" in the temperature compensation data C (t0), thereby correcting the hysteresis error due to the difference between the rise and fall of the ambient temperature, and the stable output frequency. can get.
Next, the temperature compensation data C (t1) is temperature compensated for the next change in ambient temperature.

In the above description, the bidirectional data memory circuit stores the operation program, and the microcomputer circuit calculates using this operation program to obtain the temperature compensation data. Is arbitrary, and in the present invention, any of these means may be applied during the rise and fall of the ambient temperature, respectively.

Further, in the above description, the microcomputer circuit stores and compares the last two pieces of input data to determine whether the ambient temperature is rising or falling, but other means such as, for example, Alternatively, the history of a plurality of recent data may be stored in a memory circuit, these data may be taken out and judged, and used for the calculation of the temperature compensation data.

Further, although the functional blocks are illustrated in the above description, the distribution of functions such as separation and merging is free as long as the above functions are satisfied, and the above description does not limit the present invention.

[0025]

As described above, according to the present invention, the voltage-controlled piezoelectric oscillator is considered in consideration of the ambient temperature-oscillation frequency characteristics depending on the rising and falling of the ambient temperature of the voltage-controlled piezoelectric oscillator and the changing directions of both. To obtain a microcomputer-controlled piezoelectric oscillator including a microcomputer circuit for controlling a control voltage applied to the piezoelectric oscillator. With this configuration, the hysteresis error of the ambient temperature-output frequency characteristics of the voltage controlled piezoelectric oscillator can be corrected for each of the rising and falling ambient temperatures, so that a more stable output frequency with respect to changes in the ambient temperature can be obtained. Obtainable.

[Brief description of the drawings]

FIG. 1 is a functional block diagram showing one embodiment of the present invention.

FIG. 2 is a functional block diagram showing an example of the related art.

FIG. 3 is a characteristic diagram showing an example of an ambient temperature-output frequency characteristic of a voltage controlled piezoelectric oscillator.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Voltage controlled piezoelectric oscillator 2 Bidirectional data memory circuit 3 Temperature sensor 4 Analog / digital converter 5 Microcomputer circuit 6 Digital / analog converter

Claims (4)

(57) [Claims] 1. A microcomputer-controlled piezoelectric oscillator in which a microcomputer circuit controls a control voltage applied to a voltage-controlled piezoelectric oscillator according to the ambient temperature of the voltage-controlled piezoelectric oscillator, in which the ambient temperature rises and falls and both changes. A microcomputer-controlled piezoelectric device comprising the microcomputer circuit for controlling the control voltage applied to the voltage-controlled piezoelectric oscillator in consideration of the ambient temperature-oscillation frequency characteristic of the voltage-controlled piezoelectric oscillator according to the direction. Oscillator. 2. A microcomputer-controlled piezoelectric oscillator for controlling a control voltage applied to a voltage-controlled piezoelectric oscillator by a microcomputer circuit according to the ambient temperature of the voltage-controlled piezoelectric oscillator, wherein the temperature of the ambient temperature of the voltage-controlled piezoelectric oscillator is controlled. A memory circuit that stores temperature compensation data in advance when the temperature rises and when the temperature falls, a temperature sensor that outputs an analog voltage according to the ambient temperature, and an analog / analog that inputs the analog voltage and converts it into a digital code.
A digital converter, a digital / analog converter that inputs temperature compensation data by a digital code output from the microcomputer circuit, converts the temperature compensation data into an analog voltage, and supplies the analog voltage to the voltage controlled piezoelectric oscillator, and the analog / digital conversion The recent digital code input from the instrument is stored, and whether the ambient temperature is increasing or decreasing is determined based on the stored digital code, and the changing direction is performed in cooperation with the memory circuit. And a microcomputer circuit for obtaining and outputting temperature compensation data of the control voltage based on the above. 3. The temperature compensating data stored in the memory circuit according to claim 2, wherein the temperature compensating data is an arithmetic program for calculating the temperature compensating data when the ambient temperature rises and when the ambient temperature falls, and the microcomputer is configured to store the temperature compensation data in the memory. A microcomputer-controlled piezoelectric oscillator, wherein temperature compensation data of the control voltage is calculated and output based on the changing direction by a calculation program of a circuit. 4. The memory circuit according to claim 2, wherein the history of a plurality of recent digital codes input from the analog-digital converter is stored in the memory circuit, and the microcomputer performs temperature compensation based on the history of the digital codes. A microcomputer controlled piezoelectric oscillator characterized by generating data.