JP2553281B2 - Oscillation circuit with crystal oscillator - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an oscillator circuit having a crystal oscillator, and more particularly to an overtone crystal oscillator circuit in which the crystal oscillator is driven with an overtone which is an odd multiple of the fundamental oscillation frequency. .

[0002]

2. Description of the Related Art An overtone crystal oscillating circuit is a crystal oscillating circuit adapted to drive a crystal oscillator at an overtone frequency 3f ₀ , 5f ₀ , 7f _{0 of} an odd multiple of its fundamental wave f ₀ . In a crystal oscillator circuit having an oscillation frequency of, for example, 20 MHz or more, it is difficult to form a crystal oscillator driven by a fundamental wave because of the high frequency, and therefore, an overtone crystal oscillator circuit is in practical use.

FIG. 4 is a circuit diagram showing a typical configuration of a conventional overtone crystal oscillator circuit. Crystal oscillator 1
A parallel resonance circuit 8 including a coil 6 and a variable capacitor 3 connected in series between the collector and the base of a transistor 4, a capacitor 5 between the base and the emitter, and a capacitor 6 and a coil 7 between the collector and the emitter. Are connected. Since an overtone crystal oscillator generally has a gradually increasing impedance such as a fundamental wave, a third order overtone, and a fifth order overtone, a series resonance circuit including a coil 2 and a variable capacitor 3 is used as the crystal oscillator 1 , And the variable capacitor is adjusted so that it vibrates at a desired overtone.

[0004]

As described above, in the conventional overtone crystal oscillator circuit, the crystal oscillator 1 is used.
A series resonance circuit composed of the coil 2 and the variable capacitor 3 is connected in series, and the resonance frequency of the series resonance circuit is set to a desired overtone vibration frequency. That is, a desired higher order selective tuning circuit is provided. However, depending on the crystal oscillator, the impedance at the frequency of the third overtone is too large, or the basic impedance relationship does not change with respect to the oscillation circuit, so the adjustment by the variable capacitor 3 is very troublesome, Sometimes it oscillates at the fundamental wave.

Further, when oscillating with a CMOS inverter or the like, it is difficult to connect a selective tuning circuit. Therefore, although the capacitance of the capacitor connected to the crystal unit is made small, overtone is taken out. Therefore, the capacitance is highly dependent. For example, even if a selective tuning circuit for extracting the third-order overtone is connected, the impedance of the fundamental wave becomes smaller than the impedance of the third-order overtone, so that oscillation occurs in the fundamental wave. Sometimes. In particular, it is very difficult to extract the fifth overtone with a CMOS inverter using a crystal oscillator for the third overtone.

An object of the present invention is to solve the above-mentioned conventional drawbacks and to provide an oscillation circuit having a crystal oscillator capable of stably and easily taking out an intended overtone.

An oscillation circuit having a crystal oscillator according to the present invention is connected to a crystal oscillator for a fundamental wave in series with a non-selective tuning circuit having a fundamental frequency as a resonance frequency. It is characterized in that the impedance at the fundamental vibration frequency of the feedback path including the selective tuning circuit is made relatively high to oscillate at the third overtone vibration frequency. Further, the oscillator circuit having the crystal oscillator according to the present invention is configured such that a non-selective tuning circuit having a resonance frequency of the third overtone oscillation frequency is connected in series with the crystal oscillator for the third overtone, and these crystals are connected. It is characterized in that the impedance of the feedback path including the oscillator and the non-selective tuning circuit at the third overtone vibration frequency is relatively increased to oscillate at the fifth overtone vibration frequency.

In the above-described oscillator circuit having the crystal oscillator according to the present invention, the resonance frequency of the non-selective tuning circuit is used as the fundamental signal frequency of the crystal oscillator, and the third overtone is generated as the desired oscillation frequency. The resonance frequency of the selective tuning circuit can be generated as the third-order overtone vibration frequency of the crystal unit, and the fifth-order overtone can be generated as the desired oscillation frequency. That is, in the present invention, by connecting the non-selective tuning circuit in series with the crystal unit, the impedance of the feedback path at frequencies other than the target overtone is set relative to the impedance for the target frequency. Therefore, the crystal oscillator can easily and stably oscillate with a desired overtone.

[0009]

1 is a circuit diagram showing the basic structure of an oscillator circuit having a crystal oscillator according to the present invention. In the present invention, a crystal oscillator 12 and a nonselective tuning circuit 15 composed of a parallel resonance circuit of a capacitor 13 and a coil 14 are connected in series between the base and collector of the transistor 11 to form a feedback path. In addition, a parallel circuit of a fixed capacitor 16 and a variable capacitor 17 is connected between the base and the emitter of the transistor 11, and a capacitor is connected between the collector and the emitter.
18 is connected and the output is taken out from the output capacitor 19 connected to the collector.

For example, if a crystal oscillator 12 for the fundamental wave is used and the nonselective tuning circuit 15 is tuned to the fundamental frequency, the feedback path including the crystal oscillator 12 and the nonselective tuning circuit 15 The impedance with respect to the fundamental wave is relatively higher than the impedance with respect to the third-order overtone, so that the crystal oscillator 12 does not oscillate with the fundamental wave and easily and stably oscillates with the third-order overtone. Further, if a crystal oscillator for a third overtone is used as the crystal oscillator 12 and the resonance frequency of the non-selective tuning circuit 15 is set to the frequency of the third overtone, the crystal oscillator 12 and the non-selective tuning circuit 15 for the third overtone are set. The impedance of the feedback path including the selective tuning circuit 15 becomes high, and
The next overtone can be stably obtained.

FIG. 2 is a circuit diagram showing the configuration of an embodiment of an overtone crystal oscillator circuit according to the present invention. In this example, a non-selective tuning circuit 24 including a capacitor 22 and a coil 23 is connected in series with the crystal oscillator 21 for the third overtone. The fundamental frequency of the crystal oscillator 21 is 8MHz, and the resonance frequency of the nonselective tuning circuit 24 is 3 of this fundamental frequency.
It is set to double the frequency of 24MHz and takes out 40MHz of the 5th overtone. The other end of the crystal oscillator 21 is grounded via a parallel circuit of a fixed capacitor 25 and a variable capacitor 26, and the other end of the nonselective tuning circuit 24 is connected to the base of a transistor 27. The base of the transistor 27 is connected to the connection point of the resistors 28 and 29 forming the potentiometer and is also grounded via the capacitors 30 and 31. The connection point of these capacitors 30 and 31 is connected to the emitter of the transistor 27 and is grounded via the resistor 32. Further, the collector of the transistor 27 is connected to the power supply positive terminal 34 via the resistor 33, and this power supply positive terminal is grounded via the capacitor 35. The collector of the transistor 27 is connected to the output terminal 37 via the output capacitor 36.

The impedance of the crystal oscillator 21 of this example is
22.4Ω, 13.0Ω and 30.3Ω for fundamental frequency, 3rd overtone and 5th overtone respectively
However, the impedance of the feedback path including the nonselective tuning circuit 24 is 24.6Ω, 600Ω and 48.7Ω, respectively. That is, the impedance with respect to the third overtone is relatively high, and as a result, stable oscillation occurs with the fifth overtone.

FIG. 3 shows the configuration of a second embodiment of an overtone crystal oscillator circuit according to the present invention, in which a CMOS inverter is used. A non-selective tuning circuit 44 composed of a parallel resonant circuit of a capacitor 42 and a coil 43 is connected in series with the crystal unit 41. The other end of the crystal unit 41 is grounded via the capacitor 45, and the other end of the non-selective tuning circuit 44 is grounded via the capacitor 46. Also, the crystal unit 41
And the non-selective tuning circuit 44 in series with the feedback resistor in parallel.
47 and the inverter 48 are connected.

In this example, the nonselective tuning circuit 44 is
It is tuned to the fundamental frequency of the crystal unit 41 and outputs a third overtone. That is, as the crystal oscillator 41, one having a fundamental wave frequency of 22.909 MHz is used. Impedance of the crystal oscillator 41 at the fundamental frequency 4.
The impedance is 5 Ω, and the impedance in the third overtone is 8.0 Ω. By setting the resonance frequency of the non-selective tuning circuit 44 to about 22 MHz which is equal to the fundamental wave frequency, the third overtone can be stably obtained. In this case, the impedance of the feedback path including the crystal oscillator 41 and the nonselective tuning circuit 44 is 60 with respect to the fundamental frequency.
0 Ω or more, 13.2 Ω for 3rd overtone
Is.

Further, as the crystal unit 41, the fundamental wave frequency is 8 MHz, the fundamental wave frequency, the third overtone and 5
The impedance at the next overtone is
By using 22.4, 13.0 and 30.3Ω crystal oscillators and setting the resonance frequency of the non-selective tuning circuit 44 to 24MHz, which is equal to the frequency of the third overtone, the fifth overtone can be extracted stably. . In this case, the impedance of the feedback path including the crystal oscillator 41 and the nonselective tuning circuit 44 is 24.6Ω for the fundamental frequency, the third overtone, and the fifth overtone, respectively.
600 Ω and 48.7 Ω.

The present invention is not limited to the above-described embodiment, but various changes and modifications can be added. For example, a circuit including the above-described non-selective tuning circuit or circuits around it may be integrally incorporated into the housing of the crystal unit to be configured as one electronic component.

[0017]

As described above, in the oscillation circuit having the crystal oscillator according to the present invention, the crystal oscillator for the fundamental wave is used, and the non-selective tuning circuit is tuned to the fundamental wave frequency. Taking out overtone easily and stably, using a crystal oscillator for the third overtone,
By tuning the non-selective tuning circuit to the third order overtone, the fifth order overtone can be easily and stably taken out. Further, as is apparent by comparing FIG. 1 showing the overtone oscillation circuit according to the present invention with FIG. 4 showing the conventional overtone crystal oscillation circuit, the present invention requires a desired overtone selectivity circuit. And the circuit configuration becomes simple.

[Brief description of drawings]

FIG. 1 is a circuit diagram showing a basic configuration of an oscillation circuit having a crystal resonator according to the present invention.

FIG. 2 is a circuit diagram showing a configuration of an embodiment of an overtone crystal oscillator circuit according to the present invention.

FIG. 3 is a circuit diagram showing a configuration of another embodiment of the overtone crystal oscillation circuit according to the present invention.

FIG. 4 is a circuit diagram showing a configuration of a conventional overtone crystal oscillator circuit.

[Explanation of symbols]

 11 Transistor 12 Crystal oscillator 13 Capacitor 14 Coil 15 Nonselective tuning circuit 18 Capacitor 19 Output capacitor 21 Crystal oscillator 22 Capacitor 23 Coil 24 Nonselective tuning circuit 27 Transistor 36 Output capacitor 41 Crystal oscillator 42 Capacitor 43 Coil 44 Non Selective tuning circuit 45, 46 Capacitor 47 Resistor 48 Inverter

Claims (2)

(57) [Claims] 1. A non-selective tuning circuit having a fundamental wave oscillation frequency as a resonance frequency is connected in series with a crystal oscillator for a fundamental wave, and a feedback path including the crystal oscillator and the non-selective tuning circuit is connected. An oscillating circuit having a crystal oscillator, characterized in that impedance at a fundamental vibration frequency is made relatively high to oscillate at a third overtone vibration frequency. 2. A non-selective tuning circuit having this third overtone vibration frequency as a resonance frequency is connected in series with a crystal oscillator for a third overtone, and these crystal oscillator and non-selective tuning circuit are connected. An oscillation circuit having a crystal resonator, characterized in that the impedance of the feedback path including the third overtone vibration frequency is made relatively high so as to oscillate at the fifth overtone vibration frequency.