JP2003008348A - Oscillation circuit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To stabilize an oscillation frequency even to sudden change in temperature, and at the same time to suppress power consumption in an oscillation circuit having a function for correcting the oscillation frequency according to temperature. SOLUTION: The oscillation circuit has an oscillation means 15 for carrying out oscillation operation at an oscillation frequency following a control signal, a temperature detection means 11 for generating a temperature detection signal, an A/D converter 12 for converting the temperature detection signal to a digital signal for outputting temperature data, data conversion means 13 and 14 for converting the temperature data outputted from the A/D converter into the control signal, and correction control means 16 to 19 for determining a time interval for correcting the oscillation frequency of the oscillation means according to the temperature based on plurality of temperature data.

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to a crystal oscillator and an SA.
The present invention relates to an oscillation circuit using a W (surface acoustic wave) oscillator or the like, and particularly to an oscillation circuit having a function of correcting the oscillation frequency according to temperature.

[0002]

2. Description of the Related Art Generally, it is known that the oscillation frequency of an oscillation circuit is easily affected by temperature changes. Therefore, for example, in an oscillator circuit used to measure an accurate time, such as a real-time clock, it is necessary to stabilize the oscillation frequency by correcting the oscillation frequency according to the temperature (temperature compensation).

Therefore, an oscillation circuit is used which reduces fluctuations in the oscillation frequency due to temperature changes by performing temperature compensation. FIG. 3 shows the configuration of such a conventional oscillator circuit. This oscillation circuit includes a temperature detection unit 11, an A / D converter 12, a data conversion unit 13, and a correction table 1.
4, the oscillator 15, the frequency divider 21, and the operation controller 22.

Under the control of the operation controller 22, the oscillator circuit shown in FIG. 3 performs temperature compensation as follows. The temperature detection unit 11 generates a temperature detection signal that changes according to the temperature. The A / D converter 12 converts the temperature detection signal generated by the temperature detection unit 11 into digital data. Then, the data conversion unit 13 converts the data using the correction table 14 to obtain a control signal for controlling the oscillation frequency of the oscillation unit 15. By controlling the oscillation frequency in this manner, the oscillation frequency can be stabilized.

Here, the frequency division unit 21 divides the oscillation signal output from the oscillation unit 15, and the operation control unit 22 as a frequency division signal.
Output to. The operation control unit 22, based on the frequency division signal,
Each part is controlled so that the temperature compensation operation is performed after a certain period of time has passed.

However, when the temperature compensating operation is carried out after a certain period of time elapses, if the interval of the temperature compensating operation is widened in order to reduce the power consumption, when the temperature changes abruptly, However, there is a problem in that the stability of the oscillation frequency becomes low.

On the other hand, when importance is attached to the stability of the oscillation frequency with respect to the temperature change, it is conceivable to perform the temperature compensation operation at the same intervals as in the case where the temperature change is the most abrupt, or to always perform the temperature compensation operation.

However, in the oscillator circuit shown in FIG. 3, the temperature detector 11 and the A / D converter 12 consume a larger current than the oscillator 15. For example, the oscillator 1
In No. 5, when the oscillation frequency is 32 kHz, the current consumption can be reduced to about 1 μA or less, but the temperature detection unit 11 and the A / D converter 12 consume current of about 10 μA to 100 μA. Therefore, when the temperature compensation operation is frequently performed, there is a problem that the current consumption of the entire oscillation circuit becomes significantly large.

By the way, Japanese Patent Application Publication (JP-A) No. 7-312549 discloses a basic clock source for generating a basic clock of a reception / reproduction clock, a highly accurate clock oscillation source, and a reception / reproduction clock. A PLL that synchronizes the phase of the basic clock, a correction unit that corrects the frequency of the reproduction clock in the PLL according to the frequency fluctuation of the basic clock with respect to the highly accurate clock, and the operation / non-operation of the correction unit is switched according to the temperature fluctuation. A clock correction device having a correction control means is disclosed. However, this clock correction device corrects the frequency fluctuation in the basic clock of the reception / reproduction clock by using TCXO (temperature-compensated crystal oscillator) used in the wireless system, and is a highly accurate clock oscillation source. Normal temperature compensation is performed for TCXO.

[0010]

Therefore, in view of the above points, the present invention, in an oscillator circuit having a function of correcting the oscillation frequency according to temperature, stabilizes the oscillation frequency even against a sudden temperature change. The purpose is to keep the power consumption low.

[0011]

In order to solve the above problems, an oscillator circuit according to the present invention is provided with an oscillating means for oscillating at an oscillating frequency according to a control signal, and a temperature detected by detecting the temperature. Output from the A / D converter and the A / D converter that converts the temperature detection signal generated by the temperature detection unit into a digital signal and outputs the temperature data as temperature data. Based on a plurality of temperature data sequentially output from the A / D converter, the data conversion means for converting the temperature data of the oscillation means into a control signal used to control the oscillation frequency of the oscillation means. Correction control means for deciding a time interval for correcting according to the temperature.

Here, the correction control means includes a storage section for storing a plurality of temperature data sequentially output from the A / D converter, and the difference between the values represented by the plurality of temperature data stored in the storage section is calculated. Based on this, the time interval for correcting the oscillation frequency of the oscillation means according to the temperature may be determined.

Further, the correction control means divides the oscillation signal output from the oscillation means according to the set division ratio, and a plurality of temperature data sequentially output from the A / D converter. And a frequency division ratio setting unit that sets a frequency division ratio in the variable frequency division unit, and corrects the oscillation frequency of the oscillation means according to the temperature based on the frequency division signal output from the variable frequency division unit. You may make it determine the time interval to do.

In this case, the frequency division ratio setting unit decreases the frequency division ratio when the difference between the values represented by the plurality of temperature data is larger than the first threshold value, and the value represented by the plurality of temperature data. If the difference between is smaller than the first threshold value and larger than the second threshold value, the division ratio is increased, and the difference between the values represented by the plurality of temperature data is smaller than the second threshold value. Alternatively, the division ratio may be set to a predetermined value.

Further, the correction control means operates the temperature detection means, the A / D converter, and the data conversion means at time intervals determined based on a plurality of temperature data sequentially output from the A / D converter. You may make it include the operation control part which controls in this way. Further, the data conversion means may include a correction table for converting the temperature data output from the A / D converter into control data used for controlling the oscillation frequency of the oscillation means.

According to the above configuration, in the oscillation circuit having the function of correcting the oscillation frequency according to the temperature, the time interval for performing the temperature compensation operation is determined according to the state of the temperature change, so that the rapid temperature change is prevented. On the other hand, the oscillation frequency can be stabilized, and the power consumption can be suppressed low.

[0017]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing the configuration of an oscillator circuit according to an embodiment of the present invention. Figure 1
As shown in FIG.
The / D converter 12, the data conversion unit 13, the correction table 14, and the oscillation unit 15 are included. Further, the oscillation circuit includes a variable frequency division unit 16, an operation control unit 17, and a storage unit 18 including a plurality of registers (1 to n).
And a frequency division ratio setting unit 19.

Next, the operation of the oscillator circuit according to this embodiment will be described. In order to correct the oscillation frequency according to the temperature, the temperature detection unit 11 generates a temperature detection signal that changes according to the temperature. A / D converter 12
Converts the temperature detection signal generated by the temperature detection unit 11 into a digital signal and outputs it as temperature data. The data conversion unit 13 obtains control data corresponding to the input temperature data by performing data conversion using the correction table 14, and outputs a control signal used to control the oscillation frequency of the oscillation unit 15. . This control signal may be an analog signal or a digital signal. When an analog signal is used as the control signal, the data converter 13 converts the control data into an analog control signal and outputs it. This control signal is supplied to the oscillator 15. In the oscillator 15, the oscillation frequency is controlled by changing the capacitance of the capacitor included in the oscillator circuit according to the control signal. In this way, the temperature compensation operation is performed.

The oscillation signal output from the oscillator 15 is input to the variable frequency divider 16. The variable frequency division unit 16 frequency-divides the oscillation signal based on the frequency division ratio set by the frequency division ratio setting unit 19, and outputs the frequency division signal obtained as a result. The operation control unit 17 determines the time interval until the next temperature compensation operation is performed based on the frequency division signal.

When performing the temperature compensation operation, the operation control unit 1
7 outputs a temperature detection control signal to the temperature detection unit 11 to detect the temperature. After that, the operation control unit 17 outputs an enable signal to the A / D converter 12, and the temperature detection unit 1
The output signal of 1 is converted into temperature data. Further, the operation control section 17 outputs a write control signal to the storage section 18. As a result, new temperature data is stored in the register of the storage unit 18. The operation control unit 17 also outputs a read control signal to the storage unit 18. As a result, the plurality of temperature data stored in the register are read out and supplied to the frequency division ratio setting unit 16. The frequency division ratio setting unit 16 sets the frequency division ratio in the variable frequency division unit 16 based on these temperature data.

The temperature data output from the A / D converter 12 is sequentially stored in a plurality of registers (1 to n). These temperature data are used to determine the temperature change. In order to obtain the temperature change, temperature data at at least two times are required. In the following, a case of using temperature data at two times will be described.

FIG. 2 shows changes in the detected temperature with time. As shown in FIG. 2, the temperature T ₀ is detected at the detection start time (t = 0), and the temperature T ₀ is detected at the next detection time t ₁ .
₁ is detected, and the temperature T ₂ is detected at the next detection time t ₂ .
Is detected. First, the temperature data D ₀ corresponding to the detected temperature T ₀ is stored in the register (1). After the read operation, the temperature data D ₀ is sent from the register (1) to the register (2), and the temperature data D ₁ corresponding to the detected temperature T ₁ is stored in the register (1). After the next read operation, the temperature data D ₁ is sent from the register (1) to the register (2) and the temperature data D ₂ corresponding to the detected temperature T ₂ is received.
Is stored in the register (1).

The frequency division ratio setting unit 19 uses data representing the difference between the value represented by the temperature data stored in the register (2) and the value represented by the temperature data stored in the register (1). "Temperature change data"). Referring to FIG. 2, first, temperature change data (D ₁ −) corresponding to the temperature change ΔT ₁ from the detection start time to the detection time t _1.
D ₀ ), and then detection time t ₁ to detection time t ₂
Temperature change data corresponding to the temperature change [Delta] T ₂ up to (D ₂ -
D ₁ ) is required.

Further, the frequency division ratio setting section 19 compares the value of the temperature change data with at least one threshold value. The case where two threshold values A and B are used will be described below (A> B). For example, when the value of the temperature change data is larger than the threshold value A, the frequency division ratio is decreased to shorten the time interval of the temperature compensation operation. Further, when the value of the temperature change data is smaller than the threshold value A and larger than the threshold value B, the frequency division ratio is increased to lengthen the time interval of the temperature compensation operation. Further, when the value of the temperature change data is smaller than the threshold value B, the frequency division ratio is set to a predetermined value (maximum value), and the temperature compensation operation is performed at a predetermined longest time interval. . In this way, the time interval for performing the temperature compensation operation is determined.

In the above embodiment, the case where the table is used for data conversion has been described, but the present invention is not limited to this, and a logic circuit or the like having an arithmetic or conversion function can be used. Further, in the above embodiment, the case where the register is used as the storage unit has been described, but the present invention is not limited to this, and other general storage elements can be used.

[0026]

As described above, according to the present invention, in an oscillator circuit having a function of correcting the oscillation frequency according to temperature, it is possible to stabilize the oscillation frequency even with a sudden temperature change. In addition, the power consumption can be kept low.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of an oscillator circuit according to an embodiment of the present invention.

FIG. 2 is a diagram showing a change in detected temperature with time.

FIG. 3 is a block diagram showing a configuration of a conventional oscillator circuit.

[Explanation of symbols]

11 Temperature detector 12 A / D converter 13 Data converter 14 Correction table 15 Oscillator 16 Variable divider 17 Motion control unit 18 Memory 19 Dividing ratio setting section

Claims (6)

[Claims] 1. An oscillating means for performing an oscillating operation at an oscillating frequency according to a control signal, a temperature detecting means for detecting a temperature and generating a temperature detecting signal corresponding to the detected temperature, and a temperature detecting means for generating the temperature detecting signal. A / D converter for converting the temperature detection signal to be converted into a digital signal and outputting it as temperature data, and temperature data output from the A / D converter are used for controlling the oscillation frequency of the oscillating means. Data conversion means for converting into a control signal, and correction control means for determining a time interval for correcting the oscillation frequency of the oscillation means according to temperature based on a plurality of temperature data sequentially output from the A / D converter. And an oscillation circuit including. 2. The correction control unit includes a storage unit that stores a plurality of temperature data sequentially output from the A / D converter, and stores the values represented by the plurality of temperature data stored in the storage unit. The oscillation circuit according to claim 1, wherein a time interval for correcting the oscillation frequency of the oscillation means according to the temperature is determined based on the difference. 3. The correction control means divides an oscillation signal output from the oscillating means in accordance with a set division ratio, and a plurality of sequentially output from the A / D converter. A frequency division ratio setting unit that sets a frequency division ratio in the variable frequency division unit based on temperature data of the above, and oscillates the oscillation means based on the frequency division signal output from the variable frequency division unit. 3. The time interval for correcting the frequency according to the temperature is determined.
The described oscillator circuit. 4. The frequency division ratio setting unit decreases the frequency division ratio when the difference between the values represented by the plurality of temperature data is larger than a first threshold value, and the value represented by the plurality of temperature data. If the difference between the two is smaller than the first threshold and larger than the second threshold, the frequency division ratio is increased, and the difference between the values represented by the plurality of temperature data is smaller than the second threshold. The oscillator circuit according to claim 3, wherein the frequency division ratio is set to a predetermined value in this case. 5. The temperature control means, the A / D converter, and the data converter at time intervals determined by the correction control means based on a plurality of temperature data sequentially output from the A / D converter. The oscillation circuit according to any one of claims 1 to 4, further comprising: an operation control unit that controls the operation unit and the operation unit. 6. The data conversion means includes a correction table for converting temperature data output from the A / D converter into control data used to control the oscillation frequency of the oscillation means. The oscillation circuit according to any one of Items 1 to 5.