JP2001257530A - Temperature compensated oscillator, communication equipment and electronic appliance - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a temperature compensated oscillator, communication equipment and an electronic appliance capable of outputting the output signal of a desired frequency in a short time by low consumption power with low phase noise in simple constitution. SOLUTION: The temperature compensated oscillator is provided with a voltage controlled oscillation circuit 21, a temperature compensation circuit 22 for outputting a temperature compensation voltage signal, a filter circuit 23 with a capacitor for removing noise voltage included in the temperature compensation voltage signal, a power switch circuit 26 for supplying the circuit 21 and the circuit 22 with power to be supplied for a power source terminal VCC in accordance with a standby signal ϕSTBY, and a voltage holding circuit 27 to hold the voltage of the capacitor of the circuit 23 by the circuit 27 when the supply of power to the circuit 22 is stopped.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a temperature-compensated oscillator, a communication device, and an electronic apparatus suitable for performing intermittent oscillation control, for example.

[0002]

2. Description of the Related Art Conventionally, oscillators used in electronic equipment are:
Since it is necessary to output an output signal having a stable oscillation frequency in a wide temperature range, a temperature compensated oscillator (TCXO) is used. This temperature-compensated oscillator uses a temperature compensation circuit to change the load capacitance according to the temperature,
Change the oscillation frequency of the piezoelectric vibrator according to the load capacity,
The temperature of the oscillation frequency of the piezoelectric vibrator is constantly compensated. As shown in FIG. 9, the temperature-compensated oscillator 1 has a filter circuit 2 provided between a temperature-compensated circuit 3 and a voltage-controlled oscillator (VCXO) 4 as shown in FIG. .

The temperature-compensated oscillator 1 includes an analog type in which the temperature compensating circuit 3 is constituted by an analog circuit and a digital type in which the temperature compensating circuit 3 is constituted by a digital circuit. Here, the filter circuit 2
The reason for providing is as follows. That is, when the temperature compensation circuit 3 is configured by an analog circuit, thermal noise and shot noise are generated from many resistance elements and semiconductor elements constituting the temperature compensation circuit 3.
The noise voltage Vn is added to the temperature compensation voltage Vc1 output from. Therefore, a filter circuit is provided to remove the noise voltage Vn from the output voltage Vc1 + Vn output from the temperature compensation circuit 3 and reduce the phase noise of the output signal.

FIG. 10 is a block diagram of a digital temperature-compensated oscillator. In this temperature-compensated oscillator 10, a temperature compensation circuit 3 includes, for example, a temperature sensor 3A, an analog / digital (A / D) ) Converter 3B,
It comprises a memory 3C and a digital / analog (D / A) converter 3D. That is, the temperature compensation circuit 3
A / D converter 3B converts the temperature information measured by the temperature sensor 3A from analog to digital, and converts the information into a digital signal for compensating for the temperature characteristics of the piezoelectric vibrator X (FIG. 9) stored in the memory 3C in advance. Convert and D / A converter 3D
Performs a digital / analog conversion to output a temperature compensation voltage Vc1. In this case, when a change occurs in the digital signal input to the D / A converter 3D due to a temperature change, the output voltage includes a step-like noise voltage Vn due to the resolution of the D / A converter 3D. There is.

Therefore, when the temperature compensating circuit 3 is constituted by a digital circuit, similarly to the case of being constituted by an analog circuit, the temperature compensating voltage V output by the temperature compensating circuit is obtained.
The noise voltage Vn is added to c1. Therefore, even in a digital temperature-compensated oscillator, by providing the filter circuit 2, the output voltage V
The noise voltage Vn is removed from c1 + Vn to reduce the phase noise of the output signal.

[0006]

However, FIG.
As shown in (A), in the current mobile phone device,
During reception standby, a method of intermittently receiving power by intermittently supplying power to intermittent receiving units (shown by hatched portions) including the temperature-compensated oscillators 1 and 10 from the viewpoint of reducing power consumption is adopted. The display unit and the keyboard are always supplied with power, and the transmitter is supplied with power only at the time of transmission. Here, FIG. 11B is a waveform of power supplied to the intermittent receiving unit. However, the temperature compensated oscillators 1, 10
Since the filter circuit 2 is inserted as described above, every time the power supply of the temperature-compensated oscillators 1 and 10 is turned on / off, charging and discharging of a capacitor constituting a part of the filter circuit 2 occur. It takes a long time until the temperature compensation voltage Vc1 is stabilized.

That is, FIG. 12 shows a timing chart at the time of intermittent reception of a temperature control type oscillator.
Between the time Ta and the time Tb, the temperature-compensated oscillators 1, 10
When the intermittent reception is performed by supplying power to the
(B)) At time Ta, the capacitor of the filter circuit 2 is gradually charged by the time constant of the filter circuit 2 (FIG. 12C). Therefore, the output voltage of the filter circuit gradually approaches the temperature compensation voltage Vc1, and the accurate temperature compensation voltage Vc1 is not immediately input to the voltage-controlled oscillation circuit 4. Therefore, as shown in FIG. 12 (F), the frequency f of the output signal of the temperature controlled oscillator changes to the time Ta.
Since the target frequency f0 will not be reached until a predetermined period has elapsed from, the required frequency during the receiving operation cannot be obtained immediately. Therefore, in this case, the operation time (“TCXO operation time”) shown in FIG.
It is necessary to continuously operate the temperature-controlled oscillator until the temperature reaches. Here, FIG. 12F shows the frequency deviation d of the output signal.
f (df = f−f0) / f0, and the time from the time Ta to the time Tb, that is, “TCXO operation time” is 1
The case where it is set to 00 [ms] is shown.

Therefore, in the portable telephone device, it is difficult to shorten the operation time, which is disadvantageous for reducing the power consumption. In this case, as disclosed in Japanese Patent Application Laid-Open No. H11-251836, a method of rapidly charging the capacitor of the filter circuit when the power of the oscillation circuit is turned on can be considered in order to avoid the delay of the oscillation start by the filter circuit. However, in this case, a charging circuit for rapidly charging the capacitor is required, which is disadvantageous in reducing power consumption and has a complicated circuit configuration.

SUMMARY OF THE INVENTION An object of the present invention is to provide a temperature-compensated oscillator having a simple structure, low phase noise, low power consumption and an output signal of a desired frequency in a short time, and a temperature-compensated oscillator. It is an object of the present invention to provide a communication device and an electronic device that perform the communication.

[0010]

According to a first aspect of the present invention, there is provided a temperature compensated oscillator comprising: a voltage-controlled oscillation circuit in which the frequency of an output signal changes according to a control voltage signal; A temperature compensation circuit that outputs a temperature compensation voltage signal for making the frequency of the output signal constant.
A filter circuit having a capacitance element for removing a noise voltage included in the temperature compensation voltage signal and outputting the noise voltage as the control voltage signal; and holding the voltage of the capacitance element when the operation of the temperature compensation circuit is stopped. A voltage holding circuit.

According to a second aspect of the present invention, there is provided a temperature-compensated oscillator wherein a frequency of an output signal changes in accordance with a control voltage signal, and a temperature for making the frequency of the output signal constant based on a temperature. A filter circuit that has a temperature compensation circuit that outputs a compensation voltage signal, a capacitor element, removes a noise voltage included in the temperature compensation voltage signal, and outputs the control voltage signal, and a control signal that is supplied from the outside. A power switch circuit for supplying externally supplied power to the voltage-controlled oscillation circuit and the temperature compensation circuit, and a voltage for holding the voltage of the capacitive element when the supply of power to the temperature compensation circuit is stopped. And a holding circuit.

According to a third aspect of the present invention, in the temperature compensated oscillator according to the first or second aspect, the frequency of the output signal is set to a frequency to be set based on a frequency control signal supplied from the outside. A voltage conversion circuit that outputs a frequency control voltage signal for performing the operation, and an addition circuit that adds the frequency control voltage signal to the temperature compensation voltage signal output from the filter circuit and outputs the resultant as the control voltage signal. It is characterized by.

According to a fourth aspect of the present invention, there is provided a temperature-compensated oscillator according to any one of the first to third aspects, wherein the voltage-controlled oscillation circuit comprises an oscillation circuit for oscillating a piezoelectric vibrator. And a variable capacitance element whose capacitance changes in accordance with the control voltage signal.

According to a fifth aspect of the present invention, there is provided a temperature-compensated oscillator according to any one of the first to fourth aspects, wherein components other than the piezoelectric vibrator are configured as one-chip ICs. It is characterized by:

A temperature-compensated oscillator according to a sixth aspect of the present invention is the temperature-compensated oscillator according to the fifth aspect, wherein the one-chip IC and the piezoelectric vibrator are housed in one package.

A communication device according to a seventh aspect of the present invention is a communication device having a built-in temperature-compensated oscillator and performing intermittent oscillation control of the temperature-compensated oscillator during reception standby. A temperature compensation circuit for outputting a temperature compensation voltage signal for keeping the frequency of the output signal constant based on temperature, and a capacitor, and removing the noise voltage included in the temperature compensation voltage signal to perform the control. It is characterized by comprising a filter circuit that outputs a voltage signal and a voltage holding circuit that holds the voltage of the capacitor when the operation of the temperature compensation circuit stops.

According to another aspect of the present invention, a communication apparatus includes a power supply, a temperature-compensated oscillator, and a control circuit for controlling the oscillation of the temperature-compensated oscillator. A temperature-compensated oscillator, wherein the temperature-compensated oscillator is a voltage-controlled oscillation circuit in which the frequency of an output signal changes according to a control voltage signal, and the frequency of the output signal is kept constant based on temperature. A temperature compensating circuit for outputting a temperature compensating voltage signal, a capacitor circuit, a filter circuit for removing a noise voltage included in the temperature compensating voltage signal and outputting the noise voltage as the control voltage signal, and the control circuit A power switch circuit that supplies the power of the power supply to the voltage-controlled oscillation circuit and the temperature compensation circuit in accordance with a control signal supplied from the power supply control circuit; It is characterized in that it comprises a voltage holding circuit for holding the voltage of the capacitor included in the filter circuit.

According to a ninth aspect of the present invention, there is provided the communication apparatus according to the seventh or eighth aspect, wherein the frequency of the output signal is set to a frequency to be set based on a frequency control signal supplied from the outside. A voltage conversion circuit that outputs a control voltage signal; and an addition circuit that adds the frequency control voltage signal to the temperature compensation voltage signal output from the filter circuit and outputs the same as the control voltage signal. .

A communication device according to a tenth aspect is the communication device according to any one of the seventh to ninth aspects, wherein the communication device sets the non-operation time of the oscillation control within 1 second to 10 seconds. Features.

According to another aspect of the present invention, there is provided an electronic apparatus having a built-in temperature-compensated oscillator for performing intermittent oscillation control of the temperature-compensated oscillator, wherein the temperature-compensated oscillator outputs a control voltage signal. A voltage-controlled oscillation circuit in which the frequency of the output signal changes in accordance with the temperature, a temperature compensation circuit that outputs a temperature compensation voltage signal for making the frequency of the output signal constant based on temperature, and a capacitor, A filter circuit that removes a noise voltage included in a temperature compensation voltage signal and outputs the control voltage signal as a control voltage signal, and a voltage holding circuit that holds a voltage of the capacitor when the operation of the temperature compensation circuit stops. It is characterized by.

According to a twelfth aspect of the present invention, there is provided an electronic apparatus having a power supply, a temperature-compensated oscillator, and a control circuit for controlling the oscillation of the temperature-compensated oscillator. An electronic device that performs a stable oscillation control, wherein the temperature-compensated oscillator includes a voltage-controlled oscillation circuit in which the frequency of an output signal changes in accordance with a control voltage signal, and the frequency of the output signal being constant based on temperature. A temperature compensating circuit that outputs a temperature compensating voltage signal for performing the operation, a filter circuit that has a capacitive element, removes a noise voltage included in the temperature compensating voltage signal, and outputs the same as the control voltage signal, and A power switch circuit for supplying the power of the power supply to the voltage-controlled oscillation circuit and the temperature compensation circuit in accordance with the supplied control signal, and when the supply of power to the temperature compensation circuit is stopped. It is characterized in that it comprises a voltage holding circuit for holding the voltage of the capacitor included in the serial filter circuit.

[0022]

Embodiments of the present invention will be described below with reference to the drawings.

(1) Embodiment (1-1) Configuration of Embodiment FIG. 1 is a functional block diagram showing a temperature-compensated oscillator used in a mobile phone according to an embodiment of the present invention together with peripheral components. FIG. 2 is a detailed block diagram of FIG. This temperature-compensated oscillator 20 includes a voltage-controlled oscillator 21
, A temperature compensation circuit 22, a filter circuit 23, a voltage conversion circuit 24, an adder 25, and a power switch circuit 26.
And a voltage holding circuit 27.

As shown in FIG. 2, the voltage-controlled oscillation circuit 2
1 is a piezoelectric vibrator X such as a crystal vibrator or a ceramic vibrator.
Oscillating circuit 211 and variable reactance element 2
12 and so on. This voltage controlled oscillation circuit 21
For example, a CMOS transistor having bipolar transistors Q1 and Q2 as shown in FIG. 3 and a CMOS transistor having inverters IV1 and IV2 as MOS transistors as shown in FIG. 4 are applied. In FIGS. 3 and 4, the voltage VREG is a power supply inside the oscillation circuit that is generated from the power supplied to the power supply terminal VCC of the temperature-compensated oscillator 20, although not shown in FIGS.

The temperature compensating circuit 22 has a temperature compensating voltage Vc1 for canceling a change in the frequency-temperature characteristic of the piezoelectric vibrator X.
Can be widely applied.
The temperature compensation circuit 22 includes, for example, a temperature sensor, an analog / digital conversion circuit,
It consists of a memory and a digital / analog conversion circuit, converts temperature information into a digital signal, converts it into data for temperature compensation recorded in the memory in advance, and performs digital / analog conversion on the data for temperature compensation. Accordingly, a digital type that outputs the temperature compensation voltage Vc1 or an analog type that outputs the temperature compensation voltage Vc1 using the temperature characteristics of elements such as a thermistor can be applied.

The filter circuit 23 is a low-pass filter including a resistor R1 and a capacitor (capacitance element) C, and a temperature compensation voltage V supplied from the temperature compensation circuit 22.
The noise voltage Vn included in c1 is removed. The time constant of the filter circuit 23 is set to remove a noise voltage generated in the temperature compensation circuit 21 or the like from the temperature compensation voltage Vc1.
The cutoff frequency is set to a value at which the cutoff frequency becomes about several tens Hz to several hundreds Hz.

The voltage conversion circuit 24 is a circuit that generates a frequency control voltage Vc2 based on a frequency control signal φVC supplied via a frequency control voltage input terminal VC. For example, as the voltage conversion circuit 24, reference numerals A, B,
As shown by C, a circuit having a function of changing the slope of the frequency control voltage Vc2 with respect to the frequency control signal φVC or changing the polarity of the change of the frequency control voltage Vc2 is applied.

The adder 25 includes a temperature compensation voltage Vc1 supplied through the filter circuit 23 and a frequency control voltage Vc2.
And outputs the result to the voltage-controlled oscillation circuit 21. Therefore, the voltage control type oscillation circuit 21 is controlled by the temperature compensation voltage Vc1 so that the oscillation frequency of the output signal P becomes constant even if the temperature changes, and the frequency control voltage Vc2
Is controlled so that the oscillation frequency of the output signal P becomes the frequency to be set.

The power switch circuit 26 supplies the power supplied to the power terminal VCC based on the control signal φSTBY supplied to the standby terminal STBY to the voltage-controlled oscillation circuit 2.
1 and a circuit for outputting to the temperature compensating circuit 22, and a switch SW that is turned on and off in accordance with a control signal φSTBY input to the standby terminal STBY. That is, by inputting the control signal φSTBY to the standby terminal STBY, the temperature-compensated oscillator 20 can start or stop oscillation by an external control circuit. Although FIG. 2 shows a configuration in which the pull-up resistor R2 is provided, this is not an essential component of the present invention, and the pull-up resistor R2 may be omitted. Therefore, in the conventional temperature-compensated oscillator that does not include the power switch circuit and the standby terminal STBY, it is necessary to perform on-off control of the power supplied to the power terminal VCC to control oscillation start and the like. Is required to provide a switch circuit outside the power supply terminal VCC, whereas the temperature-compensated oscillator 20 does not need the switch circuit 26 since it is provided inside. Thereby, the temperature compensated oscillator 2
0 is such that intermittent oscillation control can be easily performed simply by inputting a control signal φSTBY from the external intermittent oscillation power supply control circuit 30 to the standby terminal STBY.

The voltage holding circuit 27 includes the power switch circuit 2
6 is a circuit for holding the voltage of the capacitor C of the filter circuit 23 when the switch SW is off. One end of the current control resistor R3 connected to the switch SW of the power supply switch circuit 26, and the collector is connected to the filter circuit 23. And a PNP-type bipolar transistor (hereinafter, referred to as “transistor”) Tr connected to the capacitor C of FIG. Therefore, when the switch SW of the power switch circuit 26 is turned on, a current is supplied to the emitter of the transistor Tr, the impedance between the collector and the base of the transistor Tr becomes extremely small, and the voltage holding circuit 27 is connected to the collector. A current path for the capacitor C is formed. On the other hand, the voltage holding circuit 27
When the switch SW of the power switch circuit 26 is turned off,
When viewed from the collector of the transistor Tr, the impedance between the base and the base increases, so that a potential difference between both ends of the capacitor C does not occur, and the charge accumulated in the capacitor C is prevented from being discharged from the resistor R1. Is maintained.

(1-2) Operation of Embodiment Next, referring to a timing chart shown in FIG.
The operation at the time of the intermittent reception of the temperature compensated oscillator 20 will be described. In FIG. 6, the operation time of reception (TCXO
It is assumed that the operation time) and the non-operation time (TCXO stop time) are set to 40 [ms] and 680 [ms], respectively. First, as shown in FIG. 6A, when the power of the mobile phone device is turned on at time T1, initialization of the mobile phone device is started, and at the same time, as shown in FIG.
, The control signal φSTBY input to the standby terminal STBY rises to the H level.

Accordingly, in the temperature-compensated oscillator 20, the switch SW of the power switch circuit 26 is turned on, and the power from the power terminal VCC is supplied to the voltage-controlled oscillator circuit 2.
1 and the temperature compensation circuit 22. When the switch SW of the power switch circuit 26 is turned on, the power terminal VC is connected to the emitter of the transistor Tr of the voltage holding circuit 27.
Current is supplied from C, the impedance between the collector and the base becomes extremely small, and a voltage Vc3 is generated on the voltage holding circuit 27 side of the capacitor C of the filter circuit 23 as shown in FIG. Therefore, when the output of the temperature compensation voltage Vc1 from the temperature compensation circuit 22 is started,
A potential difference between the temperature compensation voltage Vc1 and the voltage Vc3 is generated in the capacitor C, and a current I (C) corresponding to the potential difference flows through the capacitor C as shown in FIG. And FIG.
As shown in (E), the potential difference Vc1 across the capacitor C is obtained.
When charging is performed until −Vc3 becomes substantially equal to the temperature compensation voltage Vc1 (time T2), the charging of the capacitor C by the temperature compensation voltage Vc1 ends, and the frequency of the output signal P is stabilized at the target frequency.

In this case, during the period from time T1 to time T2, the temperature-compensated voltage Vc1 is used for charging the capacitor C, so that the voltage-controlled oscillating circuit 21 outputs the output signal P of the frequency whose temperature is accurately compensated. Is not output. However, the period from the time T1 to the time T3 is a period spent for initialization of the mobile phone device or the like, and a practical problem occurs even if the output signal P of the frequency whose temperature is accurately compensated is not output during this period. Absent. Accordingly, the temperature-compensated oscillator 20 completes charging the capacitor C of the filter circuit 23 during initialization of the mobile phone.

Then, as shown in FIG.
3, when the initialization of the mobile phone device is completed, the control signal φSTBY from the intermittent oscillation control circuit 30 is output.
Falls to the L level. Therefore, the temperature compensated oscillator 2
At 0, the switch SW of the power switch circuit 26 is turned off, the supply of power to the voltage-controlled oscillation circuit 21 and the temperature compensation circuit 22 is stopped, and the output of the output signal P is stopped (see FIG. )). At this time, when the switch SW of the power switch circuit 26 is turned off, the supply of current to the emitter of the transistor Tr of the voltage holding circuit 27 is stopped, and the impedance between the collector and the base of the transistor Tr increases. As a result, the charge stored in the capacitor C of the filter circuit 23 is held, and the voltage of the capacitor C is held at the voltage at the time when the switch SW is turned off.

Therefore, as shown in FIG.
4, when the control signal φSTBY from the intermittent oscillation control circuit 30 rises to the H level again, the capacitor C holds a predetermined voltage, and thus the temperature compensation voltage Vc
1 is immediately output to the voltage controlled oscillation circuit 21 without being delayed by the filter circuit 23. This allows the voltage-controlled oscillation circuit 21 to immediately output the output signal P having a frequency accurately temperature-compensated by the temperature compensation voltage Vc1 (FIG. 6F). In the case of such an intermittent oscillation, if the temperature changes during the intermittent period, the temperature compensation voltage Vc1 changes. However, since the temperature change during the non-operation time is very small, the temperature compensation voltage Vc1 changes. , The frequency deviation of the output signal P when the capacitor C is charged is extremely small and poses no practical problem.

(1-3) Effects of the Embodiment According to the above configuration, the temperature-compensated oscillator 20 according to the embodiment includes the voltage holding circuit 27 provided between the power supply switch circuit 26 and the filter circuit 23, By holding the voltage of the capacitor C of the filter circuit 23 during the non-operation time, even if the phase noise of the output signal P is reduced by the filter circuit 23, the output signal P of the target frequency can be output in a short time. Can be. At this time, the temperature compensated oscillator 20
By preventing the discharge of the charge of the capacitor C charged during the operation time and keeping the voltage, the capacitor C described in the related art does not need to be rapidly charged, and the power consumption can be reduced. . Further, the voltage holding circuit 27
Can be composed of only the transistor Tr in principle, so that the circuit configuration can be simplified.

Therefore, the portable telephone device using the temperature-compensated oscillator 20 can start the receiving operation in a short time, so that the non-operating time at the time of intermittent reception can be lengthened,
The operation time can be shortened, and the power consumption of the entire mobile phone device can be reduced. For this reason, conventionally,
Since it took several hundred [ms] to start the substantial reception, it was necessary to set the operating time longer and the non-operating time shorter accordingly. Even if the power consumption is reduced by setting the time to 1 [s] or more, the substantial reception time can be maintained at about the same level as in the related art. In addition, this mobile phone device has a non-operation time of 10
If it is set to [s] or less, it is possible to receive call information from a person who calls this mobile phone at the worst at about 10 [s], so that the power consumption can be reduced without deteriorating the usability of this mobile phone. It can be significantly reduced.

(2) Modified Example (2-1) First Modified Example In the above-described embodiment, the case where power is supplied from the power supply terminal VCC to the voltage holding circuit 27 has been described. However, instead of the power from the power supply terminal VCC, a control signal φSTBY supplied to the standby terminal STBY may be supplied to the voltage holding circuit 27, and the transistor Tr may be directly controlled by the control signal φSTBY.

(2-2) Second Modification In the above embodiment, the case where the voltage holding circuit 27 is constituted by the current control resistor R3 and the transistor Tr has been described. However, the present invention is not limited to this. In short, the voltage holding circuit 27 only needs to be a switch having a small ON resistance.
Various switching elements such as a field effect transistor can be widely applied.

(2-3) Third Modification In the above embodiment, the power supply switch circuit 26 and the standby terminal STBY are provided, and the standby terminal STBY is provided.
Equipment (intermittent oscillation power supply control circuit 30)
The present invention has been described for the case where the present invention is applied to a temperature-compensated oscillator that can perform oscillation start and stop control based on a control signal φSTBY from the power supply switch circuit 26 and the standby terminal. It goes without saying that the present invention may be applied to a temperature-compensated oscillator that does not include STBY. In this case, the voltage holding circuit 27 is connected between the power supply terminal VCC and the capacitor C of the filter circuit 23.
May be provided. Specifically, switching between the voltage Vc3 on the voltage holding circuit side of the capacitor C and GND may be performed by a switch controlled by power from the power supply terminal VCC.

(2-4) Fourth Modification In the above embodiment, the mounting state of the components constituting the temperature-compensated oscillator 20 has not been mentioned. Since a noise voltage such as the voltage Vc1 can be removed, elements constituting the temperature-compensated oscillator 20 can be integrated.

Therefore, for example, components other than the piezoelectric vibrator X of the temperature-compensated oscillator and the capacitor C which is a component of the filter circuit 23 (portion surrounded by a broken line in FIG. 2) are configured as a one-chip IC. Figure 7
As shown in FIG. 8, a ceramic package temperature-compensated oscillator sealed with a lid via a piezoelectric vibrator X is formed, or as shown in FIG. 8, a one-chip IC, a piezoelectric vibrator X and a filter circuit 23 are formed. Of the plastic package in which the capacitor C is molded and sealed. Although the one-chip IC is connected to the substrate by wire bonding in FIGS. 7 and 8, it is needless to say that a method such as flip-chip bonding (FCB) can be applied.

Further, it goes without saying that components such as the resistance element of the filter circuit 23 may be mounted on the portion C in FIGS. The effect of the present invention does not change even if the capacitor C is mounted outside the package shown in FIGS. As a result, the temperature-compensated oscillator can be reduced in size, and the number of components can be reduced to reduce the number of assembly steps and the manufacturing cost.

(2-5) Fifth Modification In the above-described embodiment, the temperature control type oscillation circuit 20 which outputs an output signal P of a predetermined frequency based on the temperature compensation voltage Vc1 and the frequency control voltage Vc2 is used. Although the case where the present invention is applied has been described, the present invention is not limited to this, and the present invention may be applied to a temperature-compensated oscillator that performs only temperature compensation of the frequency of the output signal P based only on the temperature compensation voltage Vc1. . In this case, the frequency control voltage input terminal VC, the voltage conversion circuit 24, and the adder 25 may be deleted from the temperature compensated oscillator shown in FIG.

(2-6) Sixth Modification In the above embodiment, the case where this temperature-compensated oscillator is used in a portable telephone device has been described. However, the present invention is not limited to this, and a PHS (Personal handy phone) is used. ), Other communication devices such as portable information terminal devices, and GPS (Global
It can be widely applied to temperature-compensated oscillators used in electronic devices such as receivers.

[0046]

As described above, the temperature compensated oscillator of the present invention can output an output signal of a target frequency in a short time with a simple configuration, low phase noise and low power consumption.

[Brief description of the drawings]

FIG. 1 is a functional block diagram showing a temperature-compensated oscillator according to an embodiment of the present invention together with peripheral components.

FIG. 2 is a detailed block diagram of FIG.

FIG. 3 is a circuit diagram of an example of a voltage-controlled oscillation circuit of the temperature-compensated oscillator.

FIG. 4 is a circuit diagram of an example of a voltage-controlled oscillation circuit of the temperature-compensated oscillator.

FIG. 5 is a characteristic curve diagram for explaining a voltage conversion circuit of the temperature compensated oscillator.

FIG. 6 is a timing chart at the time of intermittent reception of the temperature compensated oscillator.

FIG. 7 is a perspective view of a temperature compensated oscillator according to a fourth modification.

FIG. 8 is a perspective view of a temperature compensated oscillator according to a fourth modification.

FIG. 9 is a block diagram showing a schematic configuration of a conventional temperature compensated oscillator.

FIG. 10 is a block diagram showing a schematic configuration of a conventional digital temperature compensated oscillator.

FIG. 11A is a block diagram of a portable wireless communication device, and FIG. 11B is a waveform diagram of a voltage supplied to an intermittent receiving unit of the portable wireless communication device.

FIG. 12 is a timing chart at the time of intermittent reception of the temperature compensated oscillator.

[Explanation of symbols]

 1, 10, 20: temperature-compensated oscillator 2, 23: filter circuit 3, 22, temperature-compensated circuit 4, 21, voltage-controlled oscillator circuit, 24: voltage conversion circuit, 25: Adder 26 Power switch circuit 27 Voltage holding circuit 212 Variable reactance element C Capacitor (capacitance element) X Piezoelectric vibrator Tr PNP bipolar transistor Vc1 ... temperature compensation voltage, Vc2 ... frequency control voltage, φSTBY ... control signal, φVC ... frequency control signal.

Continued on front page F-term (reference) 5J079 AA04 BA02 BA12 BA24 BA41 BA44 CB01 DA13 DB04 EA18 FA02 FA13 FA14 FA21 FB03 FB20 FB25 FB38 FB39 FB48 GA02 GA04 GA09 HA06 HA09 HA16 HA26 HA27 HA28 HA29 KA05 5J08 CC03 CC06 CC03 CC03 CC06 EE05 FF02 FF25 KK02 KK09 KK22 LL05 MM01

Claims (12)

[Claims] 1. A voltage-controlled oscillation circuit in which the frequency of an output signal changes according to a control voltage signal, and a temperature compensation circuit that outputs a temperature-compensation voltage signal for making the frequency of the output signal constant based on temperature. A filter circuit having a capacitor, for removing a noise voltage included in the temperature compensation voltage signal, and outputting the control voltage signal as a control voltage signal; and when the operation of the temperature compensation circuit is stopped, the voltage of the capacitor is changed. And a voltage holding circuit for holding the voltage. 2. A voltage-controlled oscillation circuit in which the frequency of an output signal changes according to a control voltage signal, and a temperature compensation circuit that outputs a temperature-compensation voltage signal for making the frequency of the output signal constant based on temperature. A filter circuit having a capacitance element, removing a noise voltage included in the temperature compensation voltage signal, and outputting the control voltage signal, and a power supplied from outside according to a control signal supplied from outside, A power switch circuit that supplies the voltage-controlled oscillation circuit and the temperature compensation circuit; and a voltage holding circuit that holds a voltage of the capacitor when power supply to the temperature compensation circuit is stopped. Temperature compensated oscillator. 3. The temperature compensated oscillator according to claim 1, wherein a frequency control voltage signal for setting a frequency of said output signal to a frequency to be set is output based on a frequency control signal supplied from outside. A temperature-compensated oscillator comprising: a voltage conversion circuit that performs the above operation; and an addition circuit that adds the frequency control voltage signal to the temperature compensation voltage signal output from the filter circuit and outputs the resultant as the control voltage signal. 4. The temperature-compensated oscillator according to claim 1, wherein the voltage-controlled oscillation circuit comprises: an oscillation circuit for oscillating a piezoelectric vibrator; and a capacitor in response to the control voltage signal. And a variable capacitance element whose temperature changes. 5. The temperature compensated oscillator according to claim 1, wherein components other than the piezoelectric vibrator are configured as a one-chip IC. . 6. The temperature compensated oscillator according to claim 5, wherein the one-chip IC and the piezoelectric vibrator are housed in one package. 7. A communication device having a built-in temperature-compensated oscillator and performing intermittent oscillation control of the temperature-compensated oscillator during reception standby, wherein the temperature-compensated oscillator outputs the output based on temperature. A temperature compensation circuit for outputting a temperature compensation voltage signal for keeping the frequency of the signal constant; and a filter circuit having a capacitance element for removing a noise voltage included in the temperature compensation voltage signal and outputting the same as the control voltage signal And a voltage holding circuit for holding the voltage of the capacitance element when the operation of the temperature compensation circuit is stopped. 8. A communication system comprising a power supply, a temperature-compensated oscillator, and a control circuit for controlling the oscillation of the temperature-compensated oscillator, and performing intermittent oscillation control of the temperature-compensated oscillator when waiting for reception. An apparatus, wherein the temperature-compensated oscillator comprises: a voltage-controlled oscillation circuit in which the frequency of an output signal changes according to a control voltage signal; and a temperature-compensated voltage for making the frequency of the output signal constant based on temperature. A temperature compensating circuit that outputs a signal, a filter circuit that has a capacitive element, removes a noise voltage included in the temperature compensating voltage signal, and outputs the signal as the control voltage signal, and a control signal supplied from the control circuit. A power supply switch circuit for supplying power of the power supply to the voltage-controlled oscillation circuit and the temperature compensation circuit in response to the power supply switch circuit; and a filter circuit included when the power supply to the temperature compensation circuit is stopped. And a voltage holding circuit for holding a voltage of the capacitive element. 9. The communication device according to claim 7, wherein a voltage for outputting a frequency control voltage signal for setting a frequency of the output signal to a frequency to be set based on an externally supplied frequency control signal. A communication device, comprising: a conversion circuit; and an addition circuit that adds the frequency control voltage signal to the temperature compensation voltage signal output from the filter circuit and outputs the result as the control voltage signal. 10. The communication device according to claim 7, wherein the non-operation time of the oscillation control is set within 1 second to 10 seconds. 11. An electronic device incorporating a temperature-compensated oscillator and performing intermittent oscillation control of said temperature-compensated oscillator, wherein said temperature-compensated oscillator has a frequency of an output signal according to a control voltage signal. A voltage-controlled oscillation circuit that changes, a temperature-compensation circuit that outputs a temperature-compensated voltage signal for keeping the frequency of the output signal constant based on temperature, and a capacitive element, which are included in the temperature-compensated voltage signal. An electronic device comprising: a filter circuit that removes a noise voltage and outputs the control voltage signal as the control voltage signal; and a voltage holding circuit that holds a voltage of the capacitor when the operation of the temperature compensation circuit stops. 12. An electronic apparatus having a power supply, a temperature-compensated oscillator, and a control circuit for controlling the oscillation of the temperature-compensated oscillator, and performing intermittent oscillation control of the temperature-compensated oscillator in a predetermined case. A temperature-compensated oscillator comprising: a voltage-controlled oscillation circuit in which the frequency of an output signal changes according to a control voltage signal; and a temperature-compensated voltage signal for making the frequency of the output signal constant based on temperature. A filter circuit having a capacitance element, removing a noise voltage included in the temperature compensation voltage signal, and outputting the noise voltage as the control voltage signal, according to a control signal supplied from the control circuit. A power switch circuit that supplies the power of the power supply to the voltage-controlled oscillation circuit and the temperature compensation circuit, and includes the filter circuit when the supply of power to the temperature compensation circuit is stopped. And a voltage holding circuit for holding a voltage of the capacitive element.