JPH11214928A - Temperature compensating-type piezoelectric oscillator with frequency correction circuit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a frequency correction(AFC) control with a sufficient sensitivity, a frequency correction function and a temperature control function by adding frequency control voltage supplied from outside and compensation voltage generated in a temperature compensation part, applying it to a variable capacity element and correcting a temperature and a frequency. SOLUTION: A temperature compensation part 1-2 contains a temperature sensing element, and generates a compensation voltage to be applied to a variable capacity diode for suppressing frequency fluctuations due to temperature changes by compensating for the temperature/frequency characteristic of an oscillation part 1-1. A voltage supply part 2 converts digital data outputted from EE-PROM of an initial voltage setting part 4 into a frequency correction voltage and generates a control voltage for setting the oscillation frequency of the oscillation part 1-1 to a desired value, by applying the voltage to the piezoelectric oscillation part 1-1. A voltage addition part 5 adds the AFC voltage supplied from a portable radio machine and the like and the compensation voltage supplied from the temperature compensation part 1-2 and applies it to the variable capacity diode in the piezoelectric oscillation part 1-1, for example.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a temperature-compensated piezoelectric oscillator with a frequency correction circuit used in, for example, a network synchronizer or a portable telephone terminal. The present invention relates to a temperature-compensated crystal oscillator with a frequency correction circuit configured.

[0002]

2. Description of the Related Art In recent years, there have been remarkable improvements in frequency stability, size reduction, price reduction, etc. of piezoelectric oscillators such as crystal oscillators, which have greatly contributed to the spread of portable telephone terminals and the like. In a terminal or the like that requires high-precision frequency stability, its reference frequency source is generally controlled based on an external reference signal supplied from a base station or the like. For example, in a mobile phone system, a reference frequency source of each terminal is configured to synchronize with a reference frequency emitted from a base station. As an example, in a PDC system that is a digital mobile phone system in Japan, the frequency accuracy required for the reference frequency source of the terminal is within ± 0.3 ppm, but in practice, it is about ± 0.1 ppm with a margin. It is generally synchronized with. As described above, the reference frequency source of the PDC system is controlled so as to maintain extremely high frequency accuracy during use.

However, in order to produce a wireless terminal, a crystal oscillator is mounted on a printed board, and when soldering by reflow or the like, a thermal shock or the like mainly causes a support for the crystal blank and an electrode film on the crystal substrate. Etc. are subject to mechanical distortion, which can cause frequency changes. Further, with respect to aging in which the frequency of the crystal oscillator gradually changes over time (aging), it is difficult to accurately predict individual variations in advance from individual differences at the time of manufacturing a crystal unit used for the crystal oscillator, and it is even more difficult. Since it is virtually impossible in terms of cost to actually perform a heat resistance test or aging test on each product, heat resistance tests, aging tests, etc. are performed on samples randomly drawn from all products, Means of predicting heat resistance characteristics, aging characteristics, and the like and compensating for them are performed. However, due to the frequency change due to the thermal shock and the aging, the frequency range often exceeds the frequency range specified in the specification of the crystal oscillator. If the frequency change exceeds a specified range, it is necessary for the user to readjust the frequency of the crystal oscillator using a variable trimmer built in the crystal oscillator.

Therefore, in addition to the frequency control function synchronized with the reference frequency from the base station, a frequency control function for correcting a frequency change due to thermal shock or aging is added, and this correction frequency control voltage is applied. Memorize in the memory device,
An oscillator that can read out this as needed and use it as a control voltage for frequency correction to correct the frequency change and maintain the output frequency change within a certain value has been proposed. (Japanese Patent Application No. 9-98166)

FIG. 3 is a block diagram for generally explaining the configuration and operation principle of a VCTCXO in which this oscillator is applied to a temperature-compensated VCXO. As shown in FIG. 3, the piezoelectric oscillator having the frequency correcting function has a piezoelectric oscillator 20-.
1, a temperature compensating unit 20-2, a voltage supplying unit 21, a monitoring unit, specifically, a monitoring unit 22 for monitoring whether the A / D output data is within a preset temperature range, and an initial voltage. And a setting unit 23. The basic function included in each block will be described. The oscillation unit 20-1 includes an amplifier, a crystal oscillator, and a variable capacitance diode, and controls the voltage between both ends of the variable capacitance diode as is well known. This is a voltage-controlled crystal oscillator that controls the oscillation frequency by controlling the oscillation frequency. However, this circuit includes a first variable capacitance diode for temperature compensation and a second variable capacitance diode for synchronization and correction.

Here, the temperature compensating section 20-2 includes a temperature-sensitive element, and cancels out the temperature-frequency characteristics of the oscillating section 20-1 and suppresses a frequency change due to a temperature change by a first variable capacitor. It generates a compensation voltage to be applied to the diode and supplies temperature information to a monitoring unit 22 described later. The voltage supply unit 21 includes an initial voltage setting unit 23, which will be described later, in order to set the oscillation frequency of the oscillation unit 20-1 to a desired value.
Frequency correction voltage V _ADJ based on the signal D _{AD J} supplied from
Is generated and applied to the second variable capacitance diode of the piezoelectric oscillation unit 20-1. At this time, for example, an AFC supplied from a wireless terminal or the like equipped with the oscillator is provided.
A voltage (automatic frequency control voltage) V _AFC is simultaneously applied to the second variable capacitance diode. Further, the monitoring unit 22 determines whether the temperature at that time is within a predetermined temperature range based on the temperature information generated by the temperature compensating unit 20-2, and when the condition is satisfied, the initial voltage setting unit Sends a write enable signal to the device. The initial voltage setting unit 23 is a writable and readable memory, for example, EE-P
A ROM is provided, which has a function of converting the voltage between both ends of the second variable capacitance diode of the oscillating unit 20-1 into a digital signal and storing it in the memory based on the write enable signal.

FIG. 4 shows a configuration example in which the block diagram of FIG. 3 is expanded to a specific circuit. Output of piezoelectric oscillator (OU
TPUT), a voltage applied to the second variable capacitance diode D2 is detected by a differential amplifier U1 using an operational amplifier while a frequency within a reference is output from the differential amplifier U1.
The voltage is converted into a digital signal by an A / D converter and stored in the EE-PROM. Also, EE-PROM
Is converted into an analog voltage by a D / A converter, the voltage is applied to a differential amplifier U2, and the output is converted to the second variable capacitance diode D2.
Is applied. Here, the operation of the circuit of FIG. 4 will be briefly described. It is assumed that the differential amplifier including the operational amplifiers U1 and U2 is set to have a gain G = 1, and U1 and U2 are each a second variable capacitance diode. _-Difference voltage applied to node D2 = V _AFC -V _ADJ and reference voltage V _{AFC (0)} and D / A converter output voltage V _ADJ (IN)
The difference voltage between the output signal and the output voltage = V _{AFC ( 0)} −V _ADJ (IN) is output. Here, V _ADJ is the output voltage of the operational amplifier U2, and V _ADJ =
V _{AFC (0)} -V _ADJ (IN). Where reference voltage V _{AFC (0)}
Is equal to the center voltage of the automatic frequency control voltage (AFC voltage) V _AFC , for example, V _{AFC (0)} = + 1.5 V,
It is assumed that the output voltage of the D / A converter is V _ADJ (IN) = + 0.5 V based on data stored in advance in the EE-PROM. At this time, for example, when the crystal oscillator having the configuration shown in FIG. 4 is used for the mobile terminal of the above-described PDC system, the terminal controls the AFC voltage V _AFC to adjust the oscillation frequency of the terminal to the reference frequency supplied from the base station. Tune to the frequency.

[0008] Now, the oscillation frequency of the oscillator of FIG. 4, for example, vary aging or the like of the crystal oscillator X1, V _AFC as a result the frequency control voltage V _AFC to intended to adjust the reference frequency emitted from the base station = Consider the case where +1.7 V is required. At this time, the control signal V
The output voltage of U1 by _AFC , that is, V _AFC −V _ADJ is A /
The data is converted to digital data by the D converter, and the EE-PR
Stored in the OM. The D / A converter has an output voltage V _ADJ (IN) = + 0.5 corresponding to data read from the EE-PROM when the power is turned on by a data holding function.
V is held, and this voltage does not change until the power supply of the crystal oscillator is turned on again. Therefore, the frequency adjustment to the reference frequency of the base station is performed at V _AFC = + 1.7V.
If in completed, a second variable capacitance diode - terminal voltage applied to the de-D2 becomes _{V AFC -V A DJ = + 0.7V} .
That is, when the power supply is turned on again, if the voltage between the terminals of the diode D2 is set to +0.7 V, the central value of the AFC voltage V _AFC =
The frequency can be adjusted at +1.5 V.
Now, when the power is turned on again after performing the above operation, the _{D / A} converter output voltage is naturally set to V _{D / A} = + 0.7V. Therefore, the output voltage of the differential amplifier by U2 becomes V _ADJ = + 0.8 V by the above-described operation, and when the frequency adjustment is performed by the frequency control voltage, V _AFC = + 0.8 V
The frequency is adjusted at 1.5 V, that is, the center control voltage, and the frequency is corrected. Thus, with the circuit configuration of FIG. 4, even if the control voltage is shifted, the frequency is automatically corrected by turning on the power again. Further, it is well known that a frequency change due to a temperature change becomes more problematic than a frequency change due to aging in a crystal oscillator, and it is common to add a frequency compensating means. In the example of FIG. 4, so-called indirect temperature compensation using a compensation circuit including a plurality of thermistors and a plurality of resistors is performed.

[0009]

However, in the crystal oscillator using the above-described frequency correction circuit, the frequency correction is performed by the difference voltage between the frequency control voltage V _AFC and the frequency correction voltage V _ADJ. The variable capacitance diode D1 to which a voltage is applied cannot perform frequency control other than frequency control and frequency correction. Therefore, when frequency temperature compensation is performed using a DC voltage corresponding to the temperature as in a so-called indirect TCXO of FIG. 4, the variable capacitance diode D1 is used.
In addition, a variable frequency element such as another variable capacitance diode D2 or a device having a frequency variable function is required. Therefore, the number of frequency control elements increases, the number of components increases, and the component mounting area increases, which hinders miniaturization. Also,
Since the first variable capacitance diode D1 is connected in series to the second variable capacitance diode D2, the load capacitance value seen from the crystal unit decreases, and the load capacitance value is applied to the variable capacitance diodes D1 and D2. Since the sensitivity of the frequency change to the applied voltages V _AFC , V _ADJ , and Vcomp is reduced, there arises a problem that sufficient frequency temperature compensation cannot be performed. Further, there is a problem that the AFC frequency control sensitivity is reduced, the AFC control cannot be performed, and the oscillation frequency deviates from the reference. Providing a plurality of frequency control functions in this way causes a serious problem that any of the frequency control functions does not operate sufficiently and a desired crystal oscillator with a frequency correction function cannot be realized. The present invention has been made to solve the above problems, and has as its object to provide a crystal oscillator with a frequency correction function having a sufficiently sensitive frequency correction function AFC control, a frequency correction function and a temperature control function. I do.

[0010]

According to a first aspect of the present invention, there is provided a temperature-compensated crystal oscillator with a frequency correction circuit according to the present invention. In a temperature-compensated crystal oscillator with a frequency correction circuit comprising a voltage setting unit and a voltage supply unit, a frequency control voltage supplied from the outside and a compensation voltage generated in the temperature compensation unit are added, and this is applied to a variable capacitance element. This is a temperature-compensated crystal oscillator with a frequency correction circuit characterized by performing temperature compensation and frequency correction. According to a second aspect of the present invention, there is provided a piezoelectric oscillation unit including a crystal unit, a variable capacitance diode, and an amplifier; An initial voltage setting unit including a readable and writable memory that digitizes and stores a voltage to be supplied to the variable capacitance diode; and a voltage supply that supplies a frequency control voltage output from the initial voltage setting unit to the piezoelectric oscillation unit. And a temperature monitoring unit that determines whether the temperature information generated by the temperature compensating unit conforms to a predetermined condition, and a crystal oscillator including an externally supplied AFC voltage. And the frequency control voltage generated by the temperature compensating unit, and applies the same to one variable capacitance element to perform temperature compensation and frequency correction by AFC. It is a frequency correction temperature compensated crystal oscillator circuit characterized by.

[0011]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below in detail based on an embodiment shown in the drawings. FIG. 1 is a block diagram for generally explaining the configuration principle and operation of a VCTCXO in which a crystal oscillator with a frequency correction circuit according to the present invention is applied to a temperature-compensated VCXO. A crystal oscillator with a frequency correction circuit according to the present invention includes a piezoelectric oscillation unit 1-1 as shown in FIG.
It comprises a temperature compensating unit 1-2, a voltage supplying unit 2, a monitoring unit 3 for monitoring whether or not the ambient temperature is within a temperature compensation range, an initial voltage setting unit 4, and a voltage synthesizing unit 5. The basic function included in each block will be described. The oscillation unit 1-1 includes an amplifier, a quartz oscillator, and one variable capacitance element, for example, a variable capacitance diode. This is a voltage-controlled crystal oscillator that controls the oscillation frequency by controlling the voltage across the capacitance diode.

The temperature compensating section 1-2 includes a temperature-sensitive element and cancels the temperature-frequency characteristics of the oscillating section 1-1, and applies a voltage to the variable capacitance diode in order to suppress a frequency change due to a temperature change. It generates a power compensation voltage and supplies temperature compensation information to a monitoring unit 3 described later. And
The voltage supply unit 2 includes an EE-P of an initial voltage setting unit 4 described later.
The digital data output from the ROM is converted into a frequency correction voltage V _{AD J} (IN) by a D / A converter, and the piezoelectric oscillation unit 1-
The function of generating a control voltage for setting the oscillation frequency of the oscillating unit 1-1 to a desired value by applying the voltage to the control signal 1 is obtained. Further, the monitoring unit 3 determines whether or not the temperature at that time is within a predetermined temperature range based on the temperature information generated by the temperature compensating unit 1-2, and when the condition is satisfied, the initial voltage setting unit , A write permission signal is transmitted. The initial voltage setting unit 4 includes a writable and readable memory, for example, an EE-PROM, and stores a digital signal of the voltage between both ends of the variable capacitance diode of the oscillation unit 1-1 in the memory based on the write enable signal. Has functions. The remaining voltage adder 5 is, for example, an AFC provided from a portable wireless device or the like equipped with the oscillator.
By adding the compensation voltage Vcomp supplied from the control voltage V _AFC and a temperature compensating unit 1-2, performs the function for application to a single variable-capacitance diode in the piezoelectric oscillator unit 1-1.

FIG. 2 shows an example of a configuration in which the block diagram of FIG. 1 is expanded to a specific circuit. As shown in FIG.
The C control voltage and the temperature compensation voltage are connected to operational amplifiers U1 and U2.
FIG. 2 is different from the conventional configuration in that the voltage is added by the following. Here, the inverting amplifier composed of the operational amplifier U2 has a function of adding the output voltage of the operational amplifier U1 and the temperature compensation voltage Vcomp and applying the result to the cathode of the variable capacitance diode D1. The inverting amplifier constituted by the operational amplifier U1 can appropriately set the frequency change with respect to the AFC control voltage by adjusting the gain. The differential amplifier constituted by the operational amplifier U3 is a variable capacitance diode D.
The differential amplifier composed of an operational amplifier U4 functions to apply a voltage for frequency correction to the variable capacitance diode D1 from the output voltage of the D / A converter. The voltage V _REF is a high-precision reference voltage generated by using a Zener diode or the like, and the AFC control voltage V
Set equal to the center value of _AFC .

Further, assuming that the output voltages of the operational amplifiers U2 and U4 are V _U2 and V _U4 , respectively, a variable capacitance diode D
A voltage of V _D1 = V _U2 −V _U4 is applied to both ends of 1. Here, the reference input voltage V of the inverting amplifier composed of U1 and U2
_{The REF} and AFC control voltage center values are both set to +1.5 V, and the inverting amplification gain is set to 1 for easy explanation. At this time, the diode applied voltage V _D1 is obtained by the following equation as is apparent from the circuit configuration. V _D1 = V _U2 −V _U4 = (V comp −1.5) + (V _AFC −1.5) + V _REF −V _U4 (1) V _U4 = V _REF −V _ADJ (IN) (2) where U4 is a differential amplifier Is set to G = 1. Now
Assume that the compensation voltage Vcomp is +1.5 V, and digital data corresponding to +1.0 V is stored in the EE-PROM. When the power is turned on, the D / A converter output voltage becomes +1.0 V due to the digital data read from the EE-PROM, and the output voltage _{VU4 of the} operational amplifier U4 becomes +0.5 V. If there is no change in the oscillation frequency, the frequency adjustment is performed at the AFC control voltage center value, and the AFC control voltage V _AFC at this time is +1.5 V.

Next, for example, when the oscillation frequency of the crystal unit X1 used for the oscillator is changed due to aging or the like, the power is turned on again, AFC control is performed, and the frequency tuning is completed. AFC control voltage V _AFC is + 1.7V. In this case, the voltage V _D1 applied to the variable diode D1 is +1.2 V according to Equation 1. Therefore, in order to perform frequency correction, that is, to adjust the frequency with the AFC control voltage being the center value +1.5 V, the D1 applied voltage may be set to the above-mentioned V _D1 = + 1.2 V. Therefore the V _AFC = + V _{D 1} when the frequency adjustment lump was conducted at 1.7V, i.e. U3 output voltage V _ADJ (OU
T) is converted to digital data by an A / D converter,
This is stored in the EE-PROM. Then, when the power is turned on again, the U4 output voltage V _U4 is obtained from the equation (2) according to this data.
+0.3 V, and as is apparent from the equation (1), AF
The frequency adjustment is performed when the C control voltage is V _AFC = + 1.5V. Due to the frequency correction, V _D1 = + 1.2 V is applied to _D1 .

In the circuit configuration of FIG. 1, when the ambient temperature changes, the temperature compensation voltage Vcomp also changes, so that the AFC control voltage differs depending on the ambient temperature. Therefore, as described in Japanese Patent Application No. 9-98166, in order to perform frequency correction with a constant accuracy, a change range T1 to T2 of the ambient temperature is set in advance, and a sensor generated in proportion to the temperature is set. A control circuit CTRL that senses the voltage and permits the writing of digital data only when the change in Vcomp is within this tolerance is required.

In the above example, a quartz oscillator was used as the piezoelectric element. However, the present invention is not necessarily limited to the quartz oscillator, and a piezoelectric element using a piezoelectric material such as langasite may be used. Not even.

[0018]

Since the present invention is constructed as described above, the frequency correction function and the other frequency control functions such as temperature compensation can be performed at one frequency without using independent frequency variable elements. Since it can be realized with variable elements, the range and accuracy of frequency correction and temperature compensation can be improved, and the number of frequency variable elements such as varactor diodes, which are generally difficult to configure on an IC chip such as a transistor, is Since only one crystal oscillator is required, a low-cost and small-sized crystal oscillator with a frequency correction function can be realized.

[Brief description of the drawings]

FIG. 1 shows a block diagram of a crystal oscillator with frequency correction according to the present invention.

FIG. 2 shows a detailed diagram of a crystal oscillator with frequency correction according to the present invention.

FIG. 3 shows a block diagram of a conventional temperature-compensated crystal oscillator with a frequency correction device.

FIG. 4 shows a detailed view of a conventional temperature-compensated crystal oscillator with a frequency correction device.

[Explanation of symbols]

1-1 Oscillator 1-2 Temperature compensator 2 Power supply 3 Monitor 4 Initial voltage setting 5 Voltage adder OUT OUT Oscillation output OSC Oscillator X1・ ・ Crystal oscillator D1 ・ ・ Varactor (variable capacitance) diode C1 ・ ・ Capacitor R1 ~ R15 ・ ・ Resistance U1 ~ U4 ・ ・ Operational amplifier Temp Sensor ・ ・ Temperature sensor Temp Comp ・ ・ Temperature compensation circuit A / D ・・ A / D converter D / A ・ ・ DA converter EE-PROM ・ ・ Electrical writing ・ Erasable memory CTRL ・ ・ Writing permission ・ Non-permission judgment circuit REFRESH ・ ・ Frequency matching completed, EE- PROM write signal Vcomp temperature compensation voltage V _AFC · frequency control voltage · frequency V _ADJ (iN) ·· D1 applied voltage detection value _{V ADJ (OUT) ·· D /} a output voltage V _REF · reference voltage AFC voltage center value)

Claims (2)

[Claims] 1. A temperature-compensated crystal oscillator with a frequency correction circuit comprising an oscillating unit, a temperature compensating unit, a temperature monitoring unit, an initial voltage setting unit, and a voltage supplying unit. A temperature-compensated crystal oscillator with a frequency correction circuit characterized by adding a compensation voltage generated in step (1) and applying the same to a variable capacitance element to perform temperature compensation and frequency correction. 2. A temperature controlled piezoelectric oscillator including a piezoelectric vibrator, a variable capacitance diode and an amplifier, and a temperature including a temperature-sensitive element and generating a voltage necessary for canceling the frequency temperature characteristic of the piezoelectric oscillator. A compensating unit, an initial voltage setting unit including a readable and writable memory that digitizes and stores a voltage to be supplied to the variable capacitance diode of the piezoelectric oscillation unit, and a frequency control voltage output from the initial voltage setting unit. An AFC voltage supplied from the outside, comprising: a voltage supply unit that supplies the piezoelectric oscillation unit; and a temperature monitoring unit that determines whether temperature information generated by the temperature compensation unit meets predetermined conditions. And a frequency control voltage generated by the temperature compensating section, and applying this to the variable capacitance diode to perform temperature compensation and frequency correction by AFC. Temperature compensated piezoelectric oscillator with wave number correction circuit.