KR0122728B1 - A circuit for frequency shifting adjustment in wireless transceiver - Google Patents

Abstract

A deviation control circuit in a wireless transducer according to a frequency change is disclosed. In the circuit, a microphone receives a baseband signal. A first amplifier amplifies the output signal from the microphone. A TCXO oscillates an optional oscillating frequency. A loop filter converts an applied signal to a DC power voltage. a VCO performs an oscillating operation by using a DC voltage from a loop filter. A PLL circuit compares the frequency from the VCO with a frequency generated by a TCXO and applies the comparison result signal to the loop filter. A gain control section amplifies and applies a baseband signal to the VCO which is applied to the first amplifier according to the DC voltage from the loop filter.

Description

Frequency shift control circuit of wireless transceiver

1 is a configuration diagram of a conventional radio transceiver.

2 is a block diagram showing an application example of the frequency shift control circuit according to the present invention.

FIG. 3 is a detailed configuration diagram of the frequency shift control circuit shown in FIG.

4 is a block diagram showing another application of the frequency shift control circuit according to the present invention.

5 is a block diagram showing another example of application of the frequency shift control circuit according to the present invention.

* Explanation of symbols for main parts of the drawings

100: PLL circuit 110: loop filter

120: voltage control signal generator 40: frequency shift control circuit

120: TCXO (Temperature contorl X-tal OSCillator)

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radio transceiver, and more particularly, to a frequency shift control circuit of a radio transceiver in which a signal adjusts a frequency shift according to a frequency change when a signal is transmitted from a radio transceiver.

In general, the conventional radio transceiver is configured as shown in FIG. 1 of the accompanying drawings. Looking at the main components of the components, the PLL circuit 100, the loop filter 100 and the voltage control signal generator 120, and so on.

Looking at the function of the component is the PLL circuit 100 is a circuit for comparing the frequency generated from the voltage control signal generator 120 with the frequency generated from the Temperature Control X-tal OSCillator (TCXO) 130, The loop filter 100 is a circuit for converting the comparison output generated from the PLL circuit 100 to a DC voltage, and the voltage control signal generator 120 (VCO) uses a DC voltage applied from the loop filter 110. Oscillation circuit.

Referring to the operation of the conventional wireless transceiver configured as described above, the baseband signal input to the microphone (MIC) is amplified by the first amplifier (AMP) is input to the voltage control signal generator 120 and the voltage control signal The baseband signal input to the generator 120 and input to the voltage control signal generator 120 is applied to the carrier signal by the voltage control signal generator 120 and applied to the second amplifier AMP2. Thereafter, the signal amplified by the second amplifier AMP2 is radiated to the free space through the antenna ANT via the band pass filter BPF.

In the conventional wireless transceiver operating as described above, the same baseband signal causes a frequency shift as the frequency of the carrier signal changes. As the frequency of the carrier signal increases, the frequency shift increases, and thus the low frequency carrier signal A problem arises in that the frequency shift difference with respect to the baseband signal between the high frequency carrier signals becomes large.

An object of the present invention for solving the above problems is to control the gain of the baseband signal corresponding to the frequency of the carrier signal to reduce the frequency shift between the high frequency carrier signal and the low frequency carrier signal of the radio transceiver It is to provide a frequency bias control circuit.

A feature of the present invention for achieving the above object is a microphone (MIC) for inputting a baseband signal; A first amplifier (AMP1) for amplifying and outputting a baseband signal from the microphone (MIC); A TCXO 130 generating and outputting an arbitrary oscillation frequency; A voltage control signal generator 120 which oscillates using the applied DC voltage; A second amplifier (AMP2) for amplifying and outputting a signal applied from the voltage control signal generator (120); A band pass filter (BPF) for filtering the signal applied from the second amplifier (AMP2) and outputting it through an antenna (ANT); A loop filter 110 converting the applied comparison signal into a DC voltage and outputting the DC signal to the voltage control signal generator 120; and generating a frequency generated from the voltage control signal generator 120 at the TCXO 130. In a wireless transceiver having a PLL circuit 100 for applying a comparison signal to the loop filter 110 in comparison with the frequency, the source source (S) is the voltage control signal generator (2) through a second resistor (R2) 120 is connected to the first amplifier AMP1 through the second resistor R2 and the first resistor RL, and the drain terminal D thereof is connected to the ground terminal. The first amplifier by controlling the voltage applied to the first resistor R1 and the second resistor R2 by switching the connection between its source S and the drain terminal D according to the voltage applied to (G). Baseband applied to the voltage control signal generator 120 from AMP1 Adjusting the gain of the day in a first premises effect transistor (Trl) for adjusting the frequency deviation of the baseband signal corresponding to the carrier signal frequency change in the voltage controlled signal generator (120) and; Connected to the power supply Vcc through the third resistor R3 of its source terminal S, and its own drain terminal D is connected to the gate terminal G of the first field effect transistor Trl. At the same time, the ground filter 110 is connected to the ground terminal through a fourth resistor R4, and its own gate terminal G is connected to the ground terminal through a fifth resistor R5, and at the same time, the loop filter 110 is connected through a sixth resistor R6. A first field effect transistor Trl connected to the source source S and the drain terminal D according to a voltage applied from the loop filter 110 to the gate terminal G thereof. It includes a second field effect transistor (Tr2) for changing the voltage applied to the gate terminal (G) of.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a block diagram showing an application example of the frequency shift control circuit according to the present invention, wherein the frequency shift control circuit 140 of the present invention is connected between the first amplifier AMP1 and the voltage control signal generator 120. The frequency shift is adjusted by adjusting the baseband signals input from the first amplifier AMP1 to the voltage control signal generator 120 according to the DC voltage from the loop filter 110.

Referring to each circuit shown in FIG. 2 in detail as follows. That is, the microphone MIC outputs the baseband signal, and the first amplifier AMP1 amplifies the output signal of the microphone MIC and outputs the output signal to the frequency shift control circuit 140, and the TCXO 130 generates an arbitrary oscillation frequency. Is generated and input to the PLL circuit 100 side, the loop filter 110 converts the applied signal into a DC voltage and outputs it to the voltage control signal generator 120 and the frequency shift control circuit 140 side, the voltage control The signal generator 120 oscillates using the DC voltage applied from the loop filter 110, and the PLL circuit 100 generates the frequency generated by the voltage control signal generator 120 in the TCXO 130. The comparison signal is applied to the loop filter 110, and the frequency shift control circuit 140 applies the baseband signal applied from the first amplifier AMP1 according to the DC voltage output from the loop filter 110. Generate voltage control signal by adjusting gain The frequency shift of the carrier signal in the voltage control signal generator 120 is adjusted by applying to the signal 120.

Meanwhile, the frequency shift control circuit 140 is connected to the first field effect transistor Tr1, the second field effect transistor Tr2, and a plurality of resistors R1 to R6, as shown in FIG. 3. In the first field effect transistor Tr1, the source terminal S is connected to the voltage control signal generator 120 through the second resistor R2 and at the same time, through the second resistor R2 and the first resistor R1. Connected to the first amplifier AMP1, the drain terminal D is connected to the ground terminal, and the connection between the source terminal S and the drain terminal D is switched according to the voltage applied to the gate terminal G. By controlling the voltage across the first resistor R1 and the second resistor R2, the voltage control signal generator is controlled by adjusting the gain of the baseband signal applied from the first amplifier AMP1 to the voltage control signal generator 120. The frequency shift of the baseband signal according to the change of the carrier signal frequency at 120 is adjusted. In addition, in the second field effect transistor Tr2, the source terminal S is connected to the power supply Vcc through the third resistor R3, and the drain terminal D is the gate terminal of the first field effect transistor Tr1. It is connected to (G) and is connected to the ground terminal through the fourth resistor (R6), and is connected to the ground terminal through the gate resistor (G) fifth resistor (B5) and at the same time through the sixth resistor (R6) loop filter. A connection between the source terminal S and the drain terminal D in accordance with the voltage applied from the loop filter 110 to the gate terminal G, thereby switching the first field effect transistor Tr1. The voltage applied to the gate terminal G is changed.

Briefly describing the operation of the frequency shift control circuit 140 according to the present invention configured as described above are as follows.

The baseband signal input to the microphone MIC is amplified by the first amplifier AMP1 and applied to the frequency shift control circuit 140. In this case, the frequency shift control circuit 140 is connected to the voltage control signal generator 120 from the first amplifier AMP1 according to the output voltage of the loop filter 110 that controls the frequency of the carrier signal of the voltage control signal generator 120. By adjusting these of the applied baseband signals, the frequency shift for the baseband signal is reduced between the low frequency carrier signal and the high frequency carrier signal.

In addition, the output of the frequency shift control circuit 140 is applied to the carrier signal of the voltage control signal generator 120 is copied to the free space through the band pass filter (BPF) and the antenna (ANT).

In the above operation, the frequency shift control circuit 140 uses the DC voltage of the loop filter 110 as a control signal. In the PLL method, the loop filter 110 outputs a high DC voltage at a high frequency and a low frequency. This is because a low DC voltage is output with respect to the frequency.

Referring to Figure 3 attached to the operation of the frequency shift control circuit 140 in more detail as follows.

First, when the loop filter 110 outputs a high DC voltage and outputs a high frequency carrier signal by the voltage control signal generator 120, the gate terminal of the second field effect transistor Tr2 from the loop filter 110. Since the DC voltage applied to (G) becomes high, the second field effect transistor Tr2 is turned ON and the current id2 is increased, thereby increasing the drain terminal D of the second field effect transistor Tr2. The voltage applied to the high voltage is applied to the gate terminal G of the first field effect transistor Tr1 so that the first field effect transistor Tr1 is turned on. Then, the current id1 flowing in the second resistor R2 is increased so that the potential at the point P is lowered due to the division phenomenon, and is applied from the first amplifier AMP1 to the voltage control signal generator 120 to decrease the gain to control the voltage. Since it is applied to the signal generator 120, when the voltage control signal generator 120 outputs a carrier signal of a high frequency, the baseband signal reduces the deviation.

On the other hand, when the loop filter 110 outputs a low DC voltage and outputs a low frequency carrier signal by the voltage control signal generator 120, the gate of the second field effect transistor Tr2 is discharged from the loop filter 110. Since the DC voltage applied to the stage G is lowered, the second field effect transistor Tr2 is turned OFF to reduce the current id2, thereby reducing the drain stage D of the second field effect transistor Tr2. ) Is lowered, and a low voltage is applied to the gate terminal G of the first field effect transistor Tr1 to turn off the first field effect transistor Tr1. Then, the current id1 flowing in the second resistor R2 is decreased to increase the potential at the P point, thereby increasing the gain applied from the first amplifier AMP1 to the electric power control signal generator 120 to increase the gain. 120). Accordingly, it is possible to reduce the frequency shift with respect to the baseband signal between the low frequency carrier signal and the high frequency carrier signal output by the voltage control signal generator 120.

The frequency shift control circuit 140 according to the present invention as described above may be used as shown in Figure 4, the carrier signal output from the voltage control signal generator 10 and the second amplifier (AMP2) When transmitted through an antenna via the band pass filter 11, the frequency of the carrier signal is detected by the detector 12 and then filtered by the band pass filter 13 to input the frequency shift control circuit 140. When applied to the point A, the frequency shift control circuit 140 is input to the input point B from the first amplifier AMP1 to the gain of the baseband signal applied to the voltage control signal generator 10 side bandpass filter 13 By adjusting according to the voltage of the signal applied from), the frequency shift with respect to the baseband signal according to the change of the carrier signal frequency in the voltage control signal generator 10 is adjusted.

In addition, the frequency bias control circuit 140 according to the present invention may be used as shown in FIG. 5, but the frequency CPU 24 of the signal applied from the PLL circuit 20 to the loop filter 21 side. By applying the output sum of the D / A converter 25 to the frequency shift control circuit 140 through the input point A according to the corresponding frequency, the frequency shift control circuit 140 is the first amplifier (AMP1) The carrier signal at the voltage control signal generator 22 by adjusting the gain of the baseband signal inputted to the input point B from the control signal generator 22 side according to the voltage applied from the D / A converter 25. Adjust the frequency shift for the baseband signal as the frequency changes.

As described above, the present invention reduces the frequency shift between the high frequency carrier signal and the low frequency carrier signal by controlling the gain of the baseband signal corresponding to the frequency of the carrier signal.

Claims (1)

A microphone (MIC) for inputting a baseband signal; A first amplifier (AMP1) for amplifying and outputting a baseband signal from the microphone (MIC); A TCXO 130 generating and outputting an arbitrary oscillation frequency; A voltage control signal generator 120 which oscillates using the applied DC voltage; A second amplifier (AMP2) for amplifying and outputting a signal applied from the voltage control signal generator (120); A band pass filter (BPF) for filtering the signal applied from the second amplifier (AMP2) and outputting it through an antenna (ANT); A loop filter 110 for converting an applied comparison signal into a DC voltage and outputting the DC signal to the voltage control signal generator 120; In the wireless transceiver having a PLL circuit 100 for applying a comparison signal to the loop filter 110 by comparing the frequency generated by the voltage control signal generator 120 with the frequency generated by the TCXO 130, The source source S thereof is connected to the voltage controlled coral generator 120 side through a second resistor R2 and at the same time the first amplifier AMP1 through the second resistor R2 and the first resistor R1. Is connected to the ground terminal, and the connection between its own source terminal S and the drain terminal D is switched according to the voltage applied to its gate terminal G. The voltage is controlled by controlling the gain of the baseband signal applied to the voltage control signal generator 120 from the first amplifier AMP1 by adjusting the voltage applied to the first resistor R1 and the second resistor R2. Bay in accordance with the carrier signal frequency change in the signal generator 120 A first field-effect for controlling the frequency shift of band signal transistor (Tr1) and; The self source terminal S is connected to the power supply Vcc through the third resistor R3, the self drain terminal D is connected to the gate terminal g of the first field effect transistor Tr1, and It is connected to the ground terminal through the fourth resistor (R4), its gate terminal (G) is connected to the ground terminal through the fifth resistor (R5) and at the same time connected to the loop filter 110 through the sixth resistor (R6) The gate terminal of the first field effect transistor Tr1 is switched by switching the connection between the source terminal S and the drain terminal D according to the voltage applied from the loop filter 110 to the gate terminal G thereof. And a second field effect transistor (Tr2) for varying the voltage applied to (G).