KR20000052592A - Voltage controlled oscillator - Google Patents

Abstract

PURPOSE: A voltage control oscillator is provided for a stable oscillation in many frequency band on a oscillating circuit. CONSTITUTION: A voltage control oscillator comprises; an inductor(15) contacted between an emitter of oscillating transistor(1) and contact point of a return condenser(3,4); the cut off or on of the inductor(15) shifted to a diode(16), equivalent capacity of the both sides between the base and emitter or between the emitter and collector, which is capable of increasing more than the return condenser(3,4) by the inductor(15), then oscillation is performed in a high frequency band by the return condenser(3,4) and the equivalent capacity is increased than return condenser(3,4) in a low frequency band so as to perform stable oscillation.

Description

Voltage Controlled Oscillator {VOLTAGE CONTROLLED OSCILLATOR}

TECHNICAL FIELD The present invention relates to a voltage controlled oscillator and, for example, to a voltage controlled oscillator used in a mobile phone which is shared in two different ways.

In recent years, the common use of one mobile telephone with two different mobile telephone systems has been studied. Such a two-method shared mobile phone requires an oscillation signal of 900 MHz band and an oscillation signal of 1.7 GHz band when used in the AMPS system and the PCS system, for example.

Fig. 4 shows the main part of a conventional two-type shared cell phone, and two voltage controlled oscillators 26 and 27 are used for the cell phone 25. The first voltage controlled oscillator 26 oscillates in the 900 MHz band, for example, and the second voltage controlled oscillator 27 oscillates in the 1.7 GHz band. Any oscillation signal is selected by the switch 28, amplified by the amplifier 29, and supplied to the high frequency circuit (not shown) in the mobile telephone 25.

5 is a circuit diagram of such a voltage controlled oscillator. This oscillation circuit is a collector-ground oscillation circuit, and the collector of the oscillation transistor 31 to which the power supply voltage E is applied is grounded at high frequency by the ground capacitor 32, and between the base and the emitter, and the emitter. Feedback capacitors 33 and 34 are connected between the ground and the ground, respectively. A reactance circuit 35 is connected between the base and the ground. The reactance circuit 35 is connected in parallel to the feedback capacitors 33 and 34 connected in series, and acts as an inductance element equivalently at the oscillation frequency.

The reactance circuit 35 includes a crab capacitor 36, a DC blocking capacitor 37, a ground capacitor 38, a varactor diode 40 connected in parallel to an inductance element, for example, a coil 39 and a coil 39. And a choke coil 41 for applying a control voltage to the varactor diode 40. When the control voltage applied to the varactor diode 40 is changed, the capacity of the varactor diode 40 is changed, the equivalent inductance of the reactance circuit 35 is changed, and the oscillation frequency is changed. The oscillation frequency is determined by the equivalent inductance of the reactance circuit 35 and the parallel resonance frequency due to the series capacitance of the feedback capacitors 33 and 34 connected in series.

In addition, a resistor 42 is connected between the emitter of the oscillation transistor 31 and the ground, and a resistor 43 is connected between the base and the ground. The base is supplied with a power supply voltage E via a resistor 44. The resistor 42 is an emitter bias resistor for applying a bias voltage to the emitter, and the resistors 43 and 44 are base bias resistors for giving a bias voltage to the base.

However, in the above oscillation circuit, only stable oscillation was possible in a certain range of frequencies. In addition, even if the inductance is converted and used in a plurality of frequency bands by converting the coil 39 of the reactance circuit 35 with another coil, a narrower band that can be changed only by the change of the inductance, and the feedback capacitor 33 , 34) has a disadvantage that the quality of the rashes is deteriorated if the dose of 34) is not changed. In addition, even if one or both of the feedback capacitors 33 and 34 are used as variable capacitors or varactor diodes, the feedback capacitance is adjusted, so that the adjustment is complicated.

In other words, two oscillation circuits are provided in the conventional two-way mobile phone. For this reason, it has hindered the miniaturization or light weight of the cellular phone.

Therefore, the present invention simply provides a voltage controlled oscillator capable of stable oscillation in a plurality of frequency bands in one oscillation circuit, thereby making one oscillation circuit of a two-way common type mobile telephone, miniaturizing or reducing the size of a mobile telephone. And it aims at making price low.

1 is a circuit diagram showing an oscillation circuit of a voltage controlled oscillator of the present invention;

2 is a circuit diagram showing a main part of an oscillation circuit of the voltage controlled oscillator of the present invention;

3 is an equivalent circuit diagram showing a main part of an oscillation circuit of the voltage controlled oscillator of the present invention;

4 is a block diagram showing a main part of a conventional cellular phone;

5 is a circuit diagram showing an oscillation circuit of a conventional voltage controlled oscillator.

※ Explanation of symbols for main parts of drawing

1: oscillation transistor 3, 4: feedback capacitor

5: reactance circuit 9a: switch

9b, 9c: coil 10: varactor diode

11: choke coil 12: emitter bias resistor

15: inductance 16: diode

17 DC blocking capacitor 18 resistance

19: converted voltage terminal 20: grounding capacitor

In order to solve the above problems, the voltage controlled oscillator of the present invention connects the first capacitor and the second capacitor connected in series with each other between the base and the collector of the oscillation transistor, and connects the connection points of the first capacitor and the second capacitor. When an inductance is connected between the emitter of the oscillation transistor and oscillation in the first high frequency band, both ends of the inductance are short-circuited, and when oscillating in the second low frequency frequency band, both sides of the inductance Do not short-circuit the end, and the equivalent capacitance formed between the base and emitter and the emitter collector of the oscillation transistor by the inductance and the first and second capacitors, respectively, of the first and second capacitors, respectively. It was made larger than a capacity | capacitance.

In addition, the voltage controlled oscillator of the present invention connects a diode in parallel with the inductance to oscillate in the first frequency band with a high frequency, conduct the diode, and when the oscillation in the second frequency band with a low frequency, It was made in a barrel.

The voltage controlled oscillator of the present invention grounds the emitter of the oscillation transistor with an emitter bias resistor, installs a DC blocking capacitor connected in series with the diode, and connects the diode and the DC blocking capacitor connected in series. The conversion voltage which makes the diode conducting or non-conductive is applied to the connection point.

A circuit diagram of the voltage controlled oscillator of the present invention is shown in FIG. This oscillation circuit is a collector-ground oscillation circuit, and the collector of the oscillation transistor 1 to which the power supply voltage E is applied is grounded at high frequency by the ground capacitor 2, and between the base and the emitter and the emitter. The first feedback capacitor 3 and the second feedback capacitor 4 are respectively connected between the ground and the ground. The reactance circuit 5 is connected between the base and the ground. The reactance circuit 5 is connected in parallel to the feedback capacitors 3 and 4 connected in series, and acts as an inductance element equivalently at the oscillation frequency.

The reactance circuit 5 includes a crab capacitor 6, a DC blocking capacitor 7, a ground capacitor 8, a switch 9a which is an inductance element, for example, coils 9b and 9c and coils 9b and 9c. ), A varactor diode 10 connected in parallel to the coils 9b and 9c and a choke coil 11 for applying a control voltage to the varactor diode 10. The inductances of the coil 9b and the coil 9c are different from each other.

By converting the coils 9b and 9c by the switch 9a, the inductance of the reactance circuit 5 is greatly changed, and oscillation is possible at other frequency bands. When the control voltage applied from the choke coil 11 to the varactor diode 10 is changed, the capacity of the varactor diode 10 is changed and the oscillation frequency in each frequency band is changed. The oscillation frequency is determined by the parallel resonance frequency by the series capacitance of the feedback capacitors 3 and 4 connected in series with the equivalent inductance of the reactance circuit 5.

In addition, a resistor 12 is connected between the emitter of the oscillation transistor 1 and the ground, and a resistor 13 is connected between the base and the ground. The power supply voltage E is supplied to the base via a resistor 14. The resistor 12 is an emitter bias resistor for applying a bias voltage to the emitter, and the resistors 13 and l4 are base bias resistors for giving a bias voltage to the base.

In addition, the inductor 15 is connected between the emitter of the oscillation transistor 1 and the connection point of the feedback capacitors 3 and 4, and the diode 16 and the direct current capacitor 17 connected in series with the inductor 15 are connected. Connect in parallel. The conversion voltage from the conversion voltage terminal 19 is applied via the resistor 18 to the connection point of the diode 16 and the capacitor 17. In addition, the connection point of the resistor 18 and the conversion voltage terminal 19 is grounded by the ground capacitor 20. The converted voltage is a positive voltage when oscillating in a high frequency band and a zero or negative voltage when oscillating in a low frequency band.

The operation of the circuit of the voltage controlled oscillator shown in FIG. 1 is shown below.

The oscillation frequency band of this voltage controlled oscillator is performed by converting the coils 9b and 9c by the switch 9a. When the voltage controlled oscillator oscillates at a high frequency band, a positive voltage is applied to the diode 16, so that the diode 16 conducts, and therefore both ends of the inductor 15 are shorted at high frequency. Since the operation in this case is the same as the conventional example, the description is omitted.

On the other hand, when oscillating the voltage-controlled oscillator in a low frequency band, since a zero or negative voltage is applied to the diode 16, the diode 16 becomes non-conductive, and the inductor 15 returns the feedback capacitors 3 and 4. ) Is connected between the connection point of the and the emitter of the oscillation transistor (1).

2 is a circuit diagram of an essential part in this case. As is apparent from Fig. 2, the feedback capacitors 3 and 4 and the inductor 15 have a Y connection. 3 replaces the Y connection of FIG. 2 with the equivalent circuit of (triangle | delta) connection. At this time, if the inductance of the inductor 15 is L and the capacities of the feedback capacitors 3 and 4 are C3 and C4, respectively, the capacitor 21 and the inductance L having the capacitance C3 between the base and the emitter ( An inductance 22 having 1 + C4 / C3 is inserted in series, and an inductance (L) having an inductance (L) (1 + C3 / C4) and a capacitor 23 having a capacitance C4 between the collector and the emitter. 24) is inserted in series. The impedance Zbe between the base and emitters, and the impedance Zce between the collector and emitters, when the oscillation frequency of this voltage controlled oscillator is ωo,

Zbe = jωoL (l + C4 / C3) + l / jωoC3

Zce = jωoL (l + C3 / C4) + l / jωoC4.

At this time, since the inductor 15 needs to function to increase the capacitance inserted between the base emitter and the collector emitter more than the capacities of the feedback capacitors 3 and 4,

ωoL (l + C4 / C3) -l / ωoC3 <0

ωoL (1 + C3 / C4) -l / ωoC4 <0

Both of these must hold.

As a result, L of the inductor 15 is

L <l / ωo ^ 2 (C3 + C4) ('ωo ^ 2' represents the power of ωo)

When is satisfied, the feedback capacitance equivalently inserted between the base emitter and the collector emitter becomes larger than the capacities of the feedback capacitors 3 and 4, respectively, so that oscillation is stabilized at a low frequency band.

As described above, the inductor 15 having the inductance L in the above-described range is connected between the emitter of the oscillation transistor 1 and the connection point of the feedback capacitors 3 and 4, and both ends of the inductor 15 are connected. By short-circuit or non-short circuit, oscillation is carried out by the feedback capacitors 3 and 4 in the high frequency band, and an equivalent capacity is increased in the low frequency band than the feedback capacitors 3 and 4, so that stable oscillation is possible.

In addition, the above description has been given with respect to the oscillator circuit of the collector ground type, but may have the same effect even if the oscillation circuit of the base ground type or the collector ground type is configured.

As described above, the voltage controlled oscillator of the present invention connects an inductance between the connection point of the first feedback capacitor and the second feedback capacitor connected in series with each other and the emitter of the oscillation transistor to oscillate in the first frequency band with high frequency. When shorting both ends of the inductance and oscillating in the second low frequency band, without shorting both ends of the inductance and by the inductor and the first and second capacitors the base of the oscillation transistor. Since the equivalent capacitance formed between the emitter and the emitter collector is made larger than that of the first and second capacitors, stable oscillation can be obtained in both frequency bands. In addition, by using one inductance, the equivalent feedback capacitance between the base and the emitter and between the emitter and the collector can be changed.

In addition, the voltage controlled oscillator of the present invention connects a diode in parallel with the inductor, conducts the diode when oscillating in a first frequency band with a high frequency, and generates the diode when oscillating in a second frequency band with a low frequency. Since conduction is conducted, the equivalent feedback feedback capacity between the base emitter and the emitter collector can be easily changed.

The voltage controlled oscillator of the present invention grounds the emitter of the oscillation transistor with an emitter bias resistor, installs a DC blocking capacitor connected in series with the diode, and connects the diode and the DC blocking capacitor connected in series. Since a conversion voltage for conducting or non-conducting the diode is applied to the connection point of, the equivalent feedback capacitance between the base and the emitter and the emitter and collector can be easily changed by one conversion voltage.

Claims (3)

A first feedback capacitor and a second feedback capacitor connected in series with each other are connected between the base and the collector of the oscillation transistor, and between a connection point of the first feedback capacitor and the second feedback capacitor and an emitter of the oscillation transistor. When the inductance is connected to oscillate in the high frequency first frequency band, both ends of the inductance are shorted, and when oscillating in the second low frequency frequency band, both ends of the inductance are not shorted, and also the inductance and the The equivalent capacitance formed between the base and emitter of the oscillation transistor and between the emitter and collector by the first and second capacitors is larger than that of the first and second feedback capacitors, respectively. Controlled oscillator. The method of claim 1, A diode connected in parallel with the inductance to conduct the diode when oscillating in a first frequency band with a high frequency and to conduction of the diode when oscillating in a second frequency band with a low frequency; Controlled oscillator. The emitter of the oscillation transistor is grounded with an emitter bias resistor, and a DC blocking capacitor connected in series with the diode is provided, and the diode is turned on or off at a connection point between the diode connected in series and the DC blocking capacitor. A voltage controlled oscillator characterized by applying a converted voltage to the tube.