KR20020095555A - Device for generating multi-signals - Google Patents

Abstract

PURPOSE: A multi signal generator is provided which can achieve a high efficiency and a high integration and a low cost of a communication system and also can obtain a number of radio frequencies easily by generating a number of radio frequencies using a minimum number of PLL(Phase Locked Loop) using a frequency mixing concept. CONSTITUTION: The first PLL(100) samples a signal of the first oscillation signals(VCO1) being output from a self-oscillating mixer(102), and generates a PLL charge pump voltage as to the first oscillation signal by comparing the sampling signal with a reference signal of the first oscillation signal, and then applies it to a local oscillator(103) of the self oscillating mixer. The second PLL(101) samples a signal of the second oscillation signals(VCO2) and generates a PLL charge pump voltage by comparing the sampling signal with a reference signal as to the second oscillation signal and then supplies it as a control voltage as to a tank circuit(105). An oscillation frequency of a VOC(Voltage Controlled Oscillator) is controlled by output voltages of the first and the second PLL.

Description

Device for generating multi-signals

The present invention relates to a multi-signal generator, and more particularly, by constructing a VCO circuit using a frequency mixing concept and generating a plurality of high-frequency signals with a minimum number of PLLs to improve the integration and design efficiency of a communication system. The present invention relates to a multiple signal generator capable of doing so.

Various communication systems including a mobile communication system and an RF system require generation of a plurality of local signals at the transmitter and the receiver in order to change frequencies.

In order to generate such a local signal, a voltage controlled oscillator (VCO) is generally used.

The VCO is controlled by the input DC voltage and outputs a signal of a desired frequency. The output frequency cannot be kept constant due to external noise or thermal reasons, and thus, a phased locked loop (PLL) is used. The input DC voltage is managed. Thus, one PLL is generally required for each VCO.

For this reason, the conventional general signal oscillator generates a plurality of high frequency signals by separately providing a plurality of PLLs and VCOs when a large number of high frequency signals are required, which may increase system integration, design efficiency, and cost competitiveness. There is a problem of deterioration.

The conventional VCO has a general configuration of an amplification section, a feedback section, and a frequency tuning circuit section, but the output frequency of the amplification section is fed back and the feedback frequency is tuned. On the other hand, the characteristics of the VCO depends on its internal Q value (peak rate) .However, when the output frequency and the feedback frequency are the same as in the prior art, it is difficult to increase the Q value of the tuning circuit in the case of a VCO having a high oscillation frequency. There is a problem.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is to generate a high frequency signal using a minimum number of PLLs by using a frequency mixing concept and to expect high efficiency, integration, and cost reduction of a communication system. In addition, the present invention provides a multi-signal generator capable of easily acquiring a plurality of high-frequency signals.

In addition, another object of the present invention is to provide a multi-signal generator that can increase the Q value of the VCO by configuring the VCO circuit so that the frequency tuned by the feedback of the output of the amplifier is different.

1 is a circuit block diagram of an embodiment of a multiple signal generator according to the present invention.

2 is a circuit block diagram of another embodiment of a multiple signal generator according to the present invention;

<Description of Symbols for Main Parts of Drawings>

100,200. 1PLL101,201. 2PLL

102,202. Self Oscillating Mixer Local oscillator

104,204. First mixer 105,205. Tank circuit

106,206. Low pass filter 107,207. 2nd mixer

108,208. amplifier

In order to achieve the above object, the multi-signal generator according to the present invention is a signal generator of a communication system, which generates a first oscillation signal by voltage-controlling a local oscillator through a first PLL and is voltage-controlled by a second PLL. A tank circuit in which a pass frequency band is determined, a first mixer for mixing the pass signal of the tank circuit and the first oscillation signal to convert an output signal frequency, an output signal from the first mixer and the first oscillator And mixing the signals and outputting a pass signal of the tank circuit again and then feeding the feedback signal back to the tank circuit, wherein the first mixer and the second mixer have different mixing directions. .

As the tank circuit is controlled to pass the second oscillation signal by the second PLL, the first mixer down-mixes the second oscillation signal and the first oscillation signal passing through the tank circuit, and then outputs the same. Outputs an intermediate frequency signal through a low pass filter provided in the second mixer, the second mixer up-mixes the first oscillation signal and the intermediate frequency signal and outputs a second oscillation signal and feeds it back to the tank circuit. It is preferable.

In addition, as the tank circuit is controlled to pass the intermediate frequency signal by the second PLL, the first mixer mixes the intermediate frequency signal passing through the tank circuit and the first oscillation signal upwardly, The second oscillator outputs a second oscillation signal through a high pass filter provided, and the second mixer down-mixes the first oscillation signal and the second oscillation signal to output an intermediate frequency signal and feeds it back to the tank circuit. It is preferable.

In addition, it is preferable to further increase the signal level by providing an amplifier at the output terminal of the second mixer or the output terminal of the tank circuit.

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

1 is a circuit block diagram of an embodiment of a multi-signal generator according to the present invention.

As shown in FIG. 1, an embodiment of the multiple signal generator according to the present invention includes a first PLL 100, a second PLL 101, a self oscillating mixer 102, and a tank circuit 105. , A low pass filter 106, a second mixer 107, and an amplifier 108.

The first PLL 100 samples a part of the first oscillation signal VCO1 output from the self-oscillating mixer 102, and then compares the sampling signal with a reference signal of the first oscillation signal to compare the first oscillation signal. Generate a PLL Charge Pump voltage (control voltage 1) for VCO1 and apply it to the local oscillator 103 of the self-oscillating mixer 102.

In addition, the second PLL 101 samples a portion of the second oscillation signal VCO2 that has passed through the tank circuit, and generates a PLL charge pump voltage while comparing it with a reference signal for the second oscillation signal. It is supplied as a control voltage for the tank circuit 105.

The first PLL 100 and the second PLL 101 are configured to synchronize the first oscillation signal and the second oscillation signal with a corresponding reference signal, and control the oscillation frequency of the VOC through its output voltage.

On the other hand, a person skilled in the art can configure the first PLL 100 and the second PLL 101 as a dual PLL composed of one chip in accordance with the embodiments, thereby making it possible to simplify the circuit configuration.

The tank circuit 105 is a kind of bandpass filter having a very small bandwidth whose center frequency is varied by an input voltage. The tank circuit 105 is controlled by the PLL charge pump voltage (control voltage 2) from the second PLL 101 and is centered thereon. The frequency is adjusted to be the frequency of the second oscillation signal VCO2.

In addition, the self-oscillating mixer 102 is a kind of mixer to generate a signal itself by applying an external voltage, and to output the frequency converted by the self-oscillating signal and the external input signal mixed up or down. A circuit is constructed, the main component of which includes a first mixer 104 and a local oscillator 103.

Thus, those skilled in the art may realize the first mixer 104 and the local oscillator 103 integrally with the self-oscillating mixer 102 or configure each of them separately.

The first oscillation signal VCO1 output from the local oscillator 103 is maintained at a constant frequency by feedback control by the first PLL 100, and the first oscillation signal VCO1 of such a constant frequency is the first oscillation signal. It is input to the mixer 104 and the second mixer 107.

In addition, the first mixer 104 mixes the input signal VCO2 filtered by the tank circuit 105 and the first oscillation signal VCO1 output from the local oscillator 103, and thus the difference frequency between them. VCO2 OUT _freq -This is a top-down mixer that outputs a VCO1 OUT _freq signal.

In addition, a low pass filter 106 is provided at the output terminal of the first mixer 104 to remove the high frequency component (or the up-mixed frequency component) from the output signal, so that the first oscillation signal VCO1 and the second oscillation signal ( Purified intermediate frequency (IF Out) can be obtained with the difference frequency of VCO2).

In addition, the second mixer 107 is a bottom-up mixer that mixes an input signal and a local oscillation signal and outputs the sum frequency signal. The second mixer 107 mixes the intermediate frequency signal IF Out and the first oscillation signal VCO1 Out again. The second oscillation signal VCO2 is generated.

On the other hand, the frequency relationship between the input and output signals in the first mixer 104 and the second mixer 106 described above is made as follows.

That is, the frequency relationship of the first mixer 104 is

Input Frequency-Local Oscillation Frequency = Output Frequency

(VCO2 OUT _freq -VCO1 OUT _freq = IF OUT _freq )

Is,

In addition, the frequency relation in the second mixer 107 is

VCO1 OUT _freq + IF OUT _freq = VCO2 OUT _freq

to be.

In addition, the amplifier 108 amplifies the second oscillation signal VCO2 from the second mixer 107 to a predetermined gain ratio and feeds it back to the tank circuit 104, thereby providing a second oscillation signal VCO2. To increase the output level and increase the frequency selectivity (or Q value) for the second oscillation signal VCO2 together with the low pass filter 106 and the tank circuit 104 connected to the first mixer output stage. do.

Hereinafter, in describing an operation process of the multiple signal generator configured as described above, the process of generating the first oscillation signal VCO1, the second oscillation signal VCO2, and the intermediate frequency signal will be described in sequence.

First, in generating the first oscillation signal VCO1, the first PLL 100 applies a PLL charge pump voltage corresponding to the first oscillation signal to the local oscillator 103 of the self-oscillation mixer 102 to generate a first oscillation signal. One oscillation signal VCO1 is generated.

At this time, the first PLL 100 samples the partial signal of the first oscillation signal and adjusts the control voltage 1 in the same manner as the general signal generation method so that the first oscillation signal VCO1 is maintained at a constant frequency.

In addition, with respect to the second oscillation signal VCO2, the second PLL 101 compares the reference signal for the second oscillation signal VCO2 with the output signal from the tank circuit, and then predetermined control according to the difference. As the voltage is applied to the tank circuit 105, the tank circuit 105 is controlled such that its passing frequency band becomes the frequency of the set second oscillation signal VCO2.

Therefore, only signals in the frequency band (controlled by the frequency of the second oscillation signal) among the external noise including the various frequency signals input to the tank circuit and the feedback input signals pass.

The noise signal or the feedback signal passing through the tank circuit 105 is mixed downward with the first oscillation signal VCO1 from the local oscillator 103 by the first mixer 104 and then the low pass filter. An intermediate frequency signal IF Out, which is a difference frequency signal between the first oscillation signal VCO1 and the second oscillation signal VCO2, is generated while passing through 105.

The intermediate frequency signal IF Out and the first oscillation signal VCO1 are upwardly mixed again through the second mixer 107 to be converted into a second oscillation signal VCO2, and the second oscillation signal VCO2 is The signal level is amplified by the amplifier 108 at a predetermined gain ratio and then fed back into the tank circuit 105.

As the feedback amplification process is cyclically repeated, the second oscillation signal VCO2 is purified to a set frequency and has a sufficient signal level.

According to the multiple signal generator as described above, since only two PLL circuits (or dual PLLs) can be configured to output signals of three frequencies, one PLL is saved, and VCO1 out, VCO2 out, Since the IF out is related to each other, it has a very effective advantage for the specific communication method that requires such an association.

In addition, the signal generation principle of the VCO2 out is made of a unique structure.

That is, in general, the oscillator has the same input frequency and output frequency, but according to the present invention, the input frequency IF Out and the output frequency VCO2 Out are different from each other in the second mixer 106. Such a structure can have a great effect in terms of noise in a particular communication system from the point of view of a voltage controlled signal oscillator (VCO).

On the other hand, Figure 2 shows another embodiment of a multiple signal generator according to the present invention.

As shown in FIG. 2, another embodiment of the present invention is a self-oscillating mixer 202 comprising a first PLL 200, a second PLL 201, a local oscillator 203 and a first mixer 204, a tank. Circuit 205, high pass filter 206, second mixer 207, and amplifier 208.

The process of generating the first oscillation signal VCO1 through the first PLL 200 and the local oscillator 203 is as described with reference to FIG. 1.

In addition, in generating the second oscillation signal VCO2 and the intermediate frequency signal IF, the second PLL 201 controls feedback of the pass band of the tank circuit 205 so that the intermediate frequency signal IF passes. The first mixer 204 upwardly mixes the output signal (IF signal) from the tank circuit 205 and the first oscillation signal VCO1 from the local oscillator 203 to generate a second oscillation signal ( Outputs a VCO2, and the second mixer 207 mixes the first oscillation signal VCO1 and the second oscillation signal VCO2 downward to generate an intermediate frequency signal IF, and then the tank circuit 205. Will be fed back.

In this case, the output terminal of the first mixer 204 is provided with a high pass filter 206 to remove only the low frequency components mixed down from the output signal of the first mixer 204 so that only the up-mixed frequencies pass.

In addition, the output terminal of the second mixer 207 is provided with an amplifier 208 for increasing the gain level of the intermediate frequency signal IF to increase the signal level of the generated signal, and in particular, the tank circuit 205 has a low frequency. Since the bandpass filter operates at the intermediate frequency band, the Q selectivity is much larger than that of the high frequency tank circuit, thereby improving frequency selectivity.

On the other hand, the frequency relationship in the first and second mixers of the other embodiment described above is as follows.

That is, in the first mixer 204 which is a bottom-up mixer, the first oscillation signal frequency VCO1 Out _freq + the intermediate frequency signal IF Out _freq = the second oscillation signal frequency VCO2 Out _freq , and the second mixer that is a top-down mixer In the mixer, the first oscillation signal frequency VCO1 Out _freq is formed by the relation of the second oscillation signal frequency VCO2 Out _freq = the intermediate frequency signal IF Out _freq .

The present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the scope of the technical idea of the present invention.

According to the present invention made as described above, in a communication system generally requiring a large number of frequencies, it is possible to output a large number of high frequency signals that are required even with minimal use of a local oscillator and a PLL. Not only can the system be designed, but the number of parts can be reduced and the price can be reduced, and various frequencies can be easily generated.

Claims (5)

In the signal generator of the communication system, Generating a first oscillation signal by voltage controlling the local oscillator through the first PLL, A tank circuit whose voltage is controlled by a second PLL to determine a pass frequency band, a first mixer for mixing the pass signal of the tank circuit and the first oscillation signal to convert the frequency of the output signal, and the first mixer from the first mixer. A second mixer which mixes an output signal and the first oscillation signal and outputs a pass signal of the tank circuit again and feeds it back to the tank circuit; And the first mixer and the second mixer have different mixing directions. The method of claim 1, As the tank circuit is controlled to pass a second oscillation signal by the second PLL, The first mixer downwardly mixes the second oscillation signal and the first oscillation signal passing through the tank circuit, and outputs an intermediate frequency signal through a low pass filter provided at the output end thereof. And the second mixer is configured to upwardly mix the first oscillation signal and the intermediate frequency signal to output a second oscillation signal and feed it back to the tank circuit. The method of claim 1, As the tank circuit is controlled to pass an intermediate frequency signal by the second PLL, The first mixer upwardly mixes the intermediate frequency signal passing through the tank circuit and the first oscillation signal, and then outputs a second oscillation signal through a high pass filter provided at an output end thereof. And the second mixer down-mixes the first oscillation signal and the second oscillation signal to output an intermediate frequency signal and feeds it back to the tank circuit. The multi-signal generator according to any one of claims 1 to 3, further comprising an amplifier at an output terminal of the second mixer or an output terminal of the tank circuit to increase the signal level. 2. The apparatus of claim 1 wherein the first mixer and the local oscillator comprise a self oscillating mixer.