KR100344635B1 - Three dimension functional voltage generating circuit - Google Patents

Abstract

The present invention relates to a three-dimensional function voltage generator circuit, and more particularly, a three-dimensional function configured to apply a three-dimensional function voltage to the temperature compensation crystal oscillator so as to compensate for frequency deviation according to the temperature of the temperature compensation crystal oscillator. Relates to a voltage generator circuit.

To this end, the present invention provides a reference current generator for generating a reference current, a first amplifier and a second amplifier for amplifying and outputting a predetermined level of the input current according to the output current of the reference current generator, the first amplifier and the second A first switching unit and a second switching unit for selectively switching and outputting the output signal of the amplifier according to its level, and an inverter unit for inverting the phase of the signal output from the second switching unit to output a three-dimensional function current And a three-dimensional function current generator for converting the output three-dimensional function current into a voltage signal corresponding thereto and applied to the crystal oscillator side.

Description

THREE DIMENSION FUNCTIONAL VOLTAGE GENERATING CIRCUIT}

The present invention relates to a three-dimensional function voltage generator circuit, and more particularly, a three-dimensional function configured to apply a three-dimensional function voltage to the temperature compensation crystal oscillator so as to compensate for frequency deviation according to the temperature of the temperature compensation crystal oscillator. Relates to a voltage generator circuit.

In general, the crystal is used a lot when generating a very stable frequency, but as shown in Figure 1 frequency deviation occurs depending on the temperature. The temperature compensated crystal oscillator (TCXO) is a crystal oscillator that compensates for the frequency deviation caused by the temperature of the crystal and always outputs a stable frequency. Recently, as TCXOs become smaller and smaller, a method of compensating for frequency variation with temperature by using a one-chip IC is becoming common.

Frequency deviation with temperature occurring in the crystal oscillator can be compensated by adjusting the load capacity across the crystal. In general, the frequency deviation according to the temperature of the crystal can be expressed as a third order function as shown in Equation 1, so that the frequency deviation according to the temperature of the crystal can be compensated by applying a third order voltage to the varactor diode used as the load capacity. .

Therefore, the sum of the output voltages of the circuit generating the 3D function voltage, the circuit generating the linear voltage, and the circuit generating the constant voltage at all times can compensate for the frequency deviation according to the temperature.

On the other hand, the conventional circuit for generating a three-dimensional functional voltage is the first method using the temperature characteristics of the bipolar transistor has a method using the difference voltage of the node connected three diodes in series and the node connected two in series. .

There is also a method using an approximate three-dimensional curve generation circuit published in the temperature compensation crystal oscillator of Japanese Patent Application No. Hei 7-216195. At this time, the approximate three-dimensional curve generation circuit generates an output of an approximate third curve that approximates the third component of the crystal oscillator characteristic of the voltage controlled crystal oscillator according to the temperature detection value of the temperature detection circuit. A plurality of amplifiers having electrostatic and inverting input / output characteristics having a limiter function in which a temperature detection value of the input signal is input and limited to a constant value having a maximum value and a minimum value of an output, and a constant supplying signal having a predetermined constant level to the plurality of amplifiers, respectively And a level generator circuit and an adder for adding outputs of the plurality of amplifiers.

In other words, an approximate three-dimensional function voltage is realized by using a nonlinear characteristic in the section of the amplifier, that is, the CMOS transistor, from the linear region to the saturation region. However, in this case, the voltage signal input to the crystal oscillator is an approximate three-dimensional function voltage, which is insufficient to generate a three-dimensional function voltage capable of compensating for the frequency deviation generated by the crystal temperature change.

Accordingly, an object of the present invention is to provide a three-dimensional function voltage generator circuit capable of accurately compensating a frequency deviation caused by temperature change in a temperature compensated crystal oscillator. will be.

Figure 1 shows the deviation curve of the output frequency according to the temperature of the crystal.

2 is a three-dimensional functional voltage generator circuit diagram according to the present invention.

3 is a graph showing temperature characteristics of the currents I _T , I _T0 , and I _R according to the present invention.

4 is a graph showing temperature characteristics of the currents I _T -I _T0 and I _T0 -I _T.

5 is a graph showing the temperature characteristics of the output current (Io) according to the present invention.

6 is a circuit diagram showing the configuration of a constant current generation circuit for implementing the present invention.

7 is a circuit diagram of a bandgap reference circuit for implementing the present invention.

8 is a circuit diagram showing the configuration of the current / voltage converter according to the present invention.

Explanation of symbols on the main parts of the drawings

10 ... first amplifier, 20 ... reference current generator,

30 ... second amplifier, 40 ... first switching unit,

50 ... second switching unit, 60 ... inverter.

In the three-dimensional function voltage generator circuit according to the present invention to achieve the above object in the three-dimensional function precursor generator circuit for applying a three-dimensional function voltage to the crystal oscillator to compensate for the frequency deviation of the crystal due to temperature changes,

A reference current generator for generating a predetermined reference current,

A first amplifier and a second amplifier for amplifying and outputting an input current by a predetermined level according to the output current of the reference current generator;

A first switching unit and a second switching unit for selectively switching output signals of the first amplifier and the second amplifier according to their levels;

A three-dimensional function current generator configured to output a three-dimensional function current by an inverter part inverting a phase of the signal output from the second switching part;

And a current / voltage converter converting the output 3D functional current into a voltage signal corresponding thereto and applying the same to a crystal oscillator.

Hereinafter, the configuration and operation effects of the three-dimensional function voltage generator circuit according to the preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

2 is a circuit diagram showing the configuration of a three-dimensional function voltage generator circuit according to the present invention. As shown in FIG. 2, the three-dimensional function voltage generator circuit according to the present invention includes a reference current generator 20 for receiving a predetermined predetermined driving current and generating a reference current, and the reference current generator 20. The output signal of the first amplifier 10 and the second amplifier 30 and the first amplifier 10 and the second amplifier 30 to amplify and output the input current by a predetermined level according to the output current of And a first switching unit 40 and a second switching unit 50 for selectively switching and outputting the inverter, and an inverter unit 60 for inverting the phase of the signal output from the second switching unit 50. And a three-dimensional functional current generator for outputting the dimensional functional current, and a current / voltage converter (shown in FIG. 8) for converting the output three-dimensional functional current into a corresponding voltage signal and applying it to the crystal oscillator side.

In the above configuration, the first amplifier 10 and the second amplifier 30 of the three-dimensional function current generator are transistors Q1 and Q2 operated according to a current applied from a current source, and a current applied to an emitter stage of the transistor. And an amplifier OP1 and OP3 for receiving a signal and amplifying and outputting the signal to a predetermined level.

In addition, the first and second switching units 40 and 50 receive current signals amplified and output from the first and second amplifiers 10 and 30 to the non-inverting terminal side and are applied to the inverting terminal side. Comparing with the current signal, the operational amplifiers OP4 and OP5 turn on / off the operations of the MOS transistors M1, M3 and M2, M4 connected to the output terminal according to the difference. The inverter 60 is composed of p-channel and n-channel MOS transistors operated in conjunction with the operation of the transistor M4 so that the first switching unit 40 and the second switching unit 50 alternately operate. To control the phase of the signal output to the current / voltage converter.

Meanwhile, the reference current generator 20 generates a reference current by receiving a transistor Q3 which is turned on according to a current signal input from a current source and a current signal applied to an emitter terminal of the transistor Q3. A buffer OP2 is provided.

In this case, the first amplifier 10 and the second amplifier 30 amplify and output a predetermined level of the input current based on the current output from the reference current generator 20.

That is, in the above configuration, since the voltage V2 is controlled by the buffer OP2 to be equal to V _BE3 , the following equation (2) is obtained. In addition, since a current is generated from the V1 node to the V2 node as shown in Equation 3, a voltage as shown in Equation 4 is generated in the V1 node.

In addition, using the relationship between the base and emitter voltage and current of the bipolar transistor as shown in Equation 5, when I _T I _T0 , the voltage V1 is controlled to match the voltage between the base and emitter of transistor Q4. Equation 6 is as follows.

If the emitter areas of transistors Q1, transistors Q3, and Q4 are the same, and Equation 6 is summarized, I _R is always constant regardless of temperature, so current I ₁ is Similarly, it is proportional to the third power of the current I _T -I _T0 .

Similarly, the current I ₂ is proportional to the third power of I _T0 -I _T , depending on the temperature, as shown in Equation 8 below.

3 is a graph showing temperature characteristics of the currents I _T , I _T0 , and I _R , and FIG. 4 is a graph showing temperature characteristics of the currents I _T0 -I _T and I _T -I _T0 , as shown in FIG. 3. I _T is a current that increases linearly with temperature, and currents I _T0 and I _R are always constant currents regardless of temperature. Therefore, the currents I _R / 2 + I _T -I _T0 and I _R / 2 + I _T0 -I _T have a symmetrical functional relationship at the same temperature of the currents I _T and I _T0 as shown in FIG. 4.

Therefore, if the current I3 is designed to match the current I1, and the current I6 is designed to match the current I2, the final current Io is based on the temperature at which the currents I _T and I _T0 match, as shown in Equation 9 below. The current changes in three dimensions. 5 is a graph showing the temperature characteristics of the output current (Io) of the three-dimensional function current generator according to the present invention.

6 is a circuit diagram illustrating a configuration of a constant current generator that generates a constant current regardless of temperature. In order to make a constant current always flow regardless of temperature, such as current I _T0 or current I _R , a circuit as shown in FIG. 6 is used. In FIG. 6, the output current I _T0 is determined by the input voltage and the resistance as shown in Equation 10 below.

In addition, in the case of the current I _R , in the circuit of FIG. 6, when the resistor R _T0 is replaced with the resistor R _R , the current I _R may be configured to always generate a constant current regardless of temperature as shown in Equation 11 below. have.

On the other hand, the input voltage V _BG in FIG. 6 is provided from a bandgap reference circuit that always generates a constant output voltage regardless of temperature. 7 is a circuit diagram illustrating an example of such a bandgap reference circuit. In the band gap reference circuit, it is also necessary to generate a linear current according to temperature. Equation 12 below shows an equation regarding a current that increases linearly with temperature in the constant current generation circuit shown in FIG. 6.

Therefore, by substituting Equations 10, 11, and 12 into Equation 9, the same result as Equation 13 can be obtained.

In order to convert the current Io as shown in Equation 13 into a voltage, the final three-dimensional function voltage as shown in Equation 14 is output using the current / voltage converter as shown in FIG.

As shown in Equation 14, the output voltage Vo is determined by the ratio of the resistors Ro, R _R , R _T , and R _T0 . Offset. Therefore, when the voltage of V _REF and V _BG used as the reference voltage is stable, a stable three-dimensional output voltage can be obtained at all times.

The three-dimensional function voltage generator circuit according to the present invention is not limited to the above-described embodiments, and may be implemented in various modifications within the scope of the technical idea of the present invention.

As described above, in the three-dimensional function voltage generator circuit according to the present invention, by applying the three-dimensional function voltage to the temperature compensated crystal oscillator, a stable operation is possible by compensating for the frequency deviation caused by the temperature change of the crystal, furthermore, a relatively low voltage It is possible to operate at, and to obtain an effect of generating stable three-dimensional voltage at all times regardless of power supply voltage and fixed parameters.

Claims (1)

In the three-dimensional function precursor generator circuit for applying a three-dimensional function voltage to the crystal oscillator to compensate for the frequency deviation of the crystal due to temperature changes, A reference current generator for generating a predetermined reference current, A first amplifier and a second amplifier for amplifying and outputting an input current by a predetermined level according to the output current of the reference current generator; A first switching unit and a second switching unit for selectively switching output signals of the first amplifier and the second amplifier according to their levels; A three-dimensional function current generator for outputting a three-dimensional function current having an inverter part inverting the phase of the signal output from the second switching part; And a current / voltage converter converting the output three-dimensional functional current into a voltage signal corresponding thereto and applying the voltage to a crystal oscillator.