KR100528145B1 - A Frequency Synthesizer with Multi-band and Frequency synthesizing Method - Google Patents

Abstract

The present invention is to provide a frequency synthesizer with a built-in voltage-controlled generator is suitable for a multi-band system while implementing low power.

The multiband frequency synthesizer of the present invention includes a frequency / phase detector, a charge pump circuit, a low pass filter, a voltage controlled oscillator, a band select divide circuit, and a channel select divide circuit.

The division circuit for band selection divides the voltage control frequency of the voltage controlled oscillator by the band selection ratio and outputs the desired band frequency. The division circuit for channel selection divides the band frequency output from the division circuit for band selection by the channel selection ratio. Generates the feedback frequency input to

Description

Frequency Synthesizer with Multi-band and Frequency Synthesizing Method

The present invention relates to a multiband frequency synthesizer and a frequency synthesis method, and more particularly, to a multiband frequency synthesizer and a multiband frequency synthesis method incorporating a voltage controlled oscillator.

In a radio frequency (RF) system, the frequency synthesizer generates the required local oscillator (LO) frequency to raise or lower the frequency band of the signal. A frequency synthesizer for this purpose usually produces an output frequency with a structure based on a phase locked loop (PLL).

As shown in FIG. 1, the conventional frequency synthesizer includes a reference frequency generator 10, a phase / frequency detector (PFD) 20, a charge pump circuit 30, a low-pass filter ( 40, a low pass filter (LPF), a voltage controlled oscillator (VCO), and a frequency division circuit 60.

The reference frequency generator 10 receives an external input frequency F _OSC and generates a required frequency F _REF inside the chip.

The frequency / phase detector 20 compares the reference frequency F _REF and the voltage control frequency F _VCO output from the voltage controlled oscillator 50 to be fed back and compares the fed back frequency F _DIV to output a comparison result. The charge pump circuit 30 converts the comparison result of the frequency / phase detector 20 into a current and outputs it to the low pass filter 40.

The low pass filter 40 outputs a voltage corresponding to the current output from the charge pump circuit 30 to the voltage controlled oscillator 50, and the voltage controlled oscillator 50 corresponds to the output voltage of the low pass filter 40. Outputs the frequency (F _VCO ).

The output frequency F _VCO of the voltage controlled oscillator 50 is converted into a frequency f _div through the frequency division circuit 60 and fed back to the frequency / phase detector 20. The frequency dividing circuit 60 adjusts the dividing ratio of F _VCO and F _DIV according to a channel selection code value input from the outside through the interface 70, thereby outputting an output frequency of the voltage controlled oscillator 50. F _VCO ) to be variable.

Recently, the development of a frequency synthesizer with a voltage-controlled oscillator for low power communication systems is required, and in order to enable communication in multiple bands, the development of a multi-band frequency synthesizer is required.

The conventional frequency synthesizer shown in FIG. 1 is intended to provide a local frequency (LO frequency) required for converting a signal of one frequency band to another frequency band in an RF system, whereby the local frequency is used to cover all signal channels of the system. An output band capable of frequency conversion is required.

In such a conventional frequency synthesizer, if the oscillator is not built in, it can be programmed using an external oscillator for multi-band frequency, but in the case of the frequency synthesizer with the built-in oscillator, due to the limited frequency tuning range of the built-in oscillator, The application of the band is difficult.

In other words, the conventional frequency synthesizer with the built-in oscillator can satisfy the required band of the single band system in general, but in the system that must satisfy the multi-band, each frequency band is separated, so if the oscillator is built in, the entire frequency band is required. I can't. This is because the frequency range of the oscillator, the characteristics of the variable capacitor used, the required phase noise, and other parasitic components limit the output frequency range to some extent.

As a result, the conventional frequency synthesizer shown in FIG. 1 has a problem that it is not suitable for multi-band frequency synthesis which basically requires a wide band of frequency tuning range.

The technical problem to be achieved by the present invention is to solve the problems of the prior art as described above, and the present invention divides the programmable divider into two stages, by programming the first divider and the second divider respectively, and further, voltage control Its purpose is to provide a frequency synthesizer with a built-in oscillator that enables low power and is suitable for multi-band systems.

Multi-band frequency synthesizer according to the characteristics of the present invention for achieving the above object

A frequency / phase detector for comparing the reference frequency with the feedback frequency inputted and outputting a comparison result; A charge pump circuit converting the comparison result of the frequency / phase detector into a current; A low pass filter for generating a voltage corresponding to the current output from the charge pump circuit; A voltage controlled oscillator having a variable capacitor capable of continuous tuning and a switched capacitor capable of discrete tuning, and outputting a voltage control frequency corresponding to the output voltage of the low pass filter; A band selection division circuit for dividing a voltage control frequency of the voltage controlled oscillator by a band selection ratio and outputting a desired band frequency; And a channel selection division circuit for dividing the band frequency output from the band selection division circuit by a channel selection ratio to generate the feedback frequency input to the frequency / phase detector.

The multi-band frequency synthesizer may further include a reference frequency generator configured to receive an external input frequency and generate the reference frequency required inside the chip.

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The band select ratio of the band select divide circuit and the channel select ratio of the channel select divide circuit can be adjusted by an externally programmed code.

On the other hand, multi-band frequency synthesis method according to a feature of the present invention

a) comparing a reference frequency with a feedback frequency inputted back, and outputting a current corresponding to the comparison result; b) generating a control voltage corresponding to the current output in step a); c) outputting a voltage control frequency corresponding to the control voltage through a voltage controlled oscillator; d) dividing the voltage control frequency by a band selection ratio and outputting a predetermined band frequency; And e) generating a feedback frequency by dividing the band frequency by a channel selection ratio.

Hereinafter, with reference to the drawings will be described an embodiment of the present invention;

2 is a diagram illustrating a multi-band frequency synthesizer according to an embodiment of the present invention.

As shown in FIG. 2, the multi-band frequency synthesizer according to the embodiment of the present invention includes a reference frequency generator 100, a frequency / phase detector (PFD), a charge pump circuit 300, and a charge pump circuit 300. CP), low pass filter (400, low pass filter; LPF), voltage controlled oscillator (500, Voltage Controlled Oscillator; VCO), band selection frequency division circuit 600 and channel selection frequency division circuit 700 Include.

A reference frequency generator 100 is as for receiving an input frequency (F _OSC), the external switch to a frequency (F _REF), required within the chip, divided by dividing a constant external input frequency (F _OSC) ratio (R) based on Output the frequency F _REF . The frequency generator 100 according to the embodiment of the present invention adjusts the division ratio R according to the band selection code input from the outside through the first interface 800.

The frequency / phase detector 200 is fed back by _{dividing the} reference frequency F _REF and the voltage control frequency F _VCO output from the voltage controlled oscillator 500 into a band selection ratio B and a channel selection ratio M, respectively. The frequency F _DIV is compared and the comparison result is output.

The charge pump circuit 300 converts the comparison result of the frequency / phase detector 200 into a current and outputs it to the low pass filter 400, and the low pass filter 400 is applied to the current output from the charge pump circuit 300. The corresponding voltage is output to the voltage controlled oscillator 500.

The voltage controlled oscillator 500 outputs a frequency F _VCO corresponding to the output voltage of the low pass filter 400. The voltage controlled oscillator according to the embodiment of the present invention is capable of both discrete frequency tuning using a switched-capacitor and continuous tuning using a variable capacitor. Here, discrete frequency tuning is for coarse frequency tuning, and continuous tuning is for fine range frequency tuning.

The band selecting division circuit 600 divides the output frequency F _VCO of the voltage controlled oscillator 500 by the band selection ratio B, and outputs a desired band frequency F _wanted . At this time, according to the embodiment of the present invention, the band selection ratio B is adjusted according to the band selection code input from the outside through the first interface 800.

The channel select divide circuit 700 divides a predetermined band frequency F _wanted output from the band select divide circuit 600 by the channel select ratio M to determine a feedback frequency F _DIV fed back to the frequency / phase detector. Output At this time, according to the embodiment of the present invention, the channel selection ratio M is adjusted according to the channel selection code input from the outside through the second interface 900.

3 is a detailed circuit diagram of the voltage controlled oscillator of FIG.

As shown in FIG. 3, the voltage controlled oscillator 500 according to the embodiment of the present invention includes an inductor L, an NMOS variable capacitor for continuous frequency tuning, and a switched-capacitor c11 for discrete frequency tuning. , c12, c14, c18, c21, c22, c24, c28, NMOS switches (sw1, sw2, sw4, sw8) connected to one end of each capacitor (c11, c12, c14, c18, c21, c22, c24, c28) ) And NMOS and PMOS to compensate for energy losses.

In FIG. 3, since the capacitance of the variable capacitor Varacter varies according to the output voltages Vctl + and Vctl− of the low pass filter 400, fine tuning of the frequency is continuously performed through the phase lock operation of the frequency synthesizer. Make it possible.

The switches Sw1, sw2, sw4, sw8 connected to the switched capacitors c11, c12, c14, c18, c21, c22, c24, and c28 are connected by external band selection codes through the first interface 800. It is switched and eventually the capacitance of the switched-capacitor is varied over a wide range. In short, switched capacitors vary the frequency of the voltage-controlled oscillator discretely across an external input value.

The operation of the frequency synthesizer according to the embodiment of the present invention will be described with reference to FIGS. 2 and 3.

First, a band selection code and a channel selection code are input through the first interface 800 and the second interface 900, respectively, for use of the frequency synthesizer. The input band selection code programs the frequency generator 100, the voltage controlled oscillator 500, and the band selection division circuit 600. Specifically, the input band selection code adjusts the division ratio R of the frequency generator 100 and the band selection ratio B of the division circuit for band selection, and operates a switched capacitor of the voltage controlled oscillator 500. Outputs the frequency (F _VCO ) of the band. In addition, the input channel selection code adjusts the channel selection ratio M of the channel selection division circuit 700.

For example, according to an embodiment of the present invention, the operating frequency F _VCO of the voltage controlled oscillator 500 is output by the band selection code, and the output operating frequency F _VCO is divided by the band selection division circuit 600. Is divided by the band selection ratio B adjusted by the band selection code, and the frequency F _wanted of the desired band is output. At this time, according to the embodiment of the present invention, since the design of a very high frequency voltage controlled oscillator is difficult, the band selection ratio B is set to a small value.

The output frequency F _wanted is divided by the channel selection ratio M adjusted by the channel selection code by the channel selection division circuit 700 to output the final frequency F _DIV .

In the frequency synthesizer according to the embodiment of the present invention, the frequency relationship of each output is expressed by the following equation.

4 shows a specific use example of the structure of the multi-band frequency synthesizer according to the embodiment of the present invention. In FIG. 4, an example in which multiple bands of 900 MHz, 1.5 GHz, 1.8 GHz, 2 GHz, and 2.4 GHz is implemented with one frequency synthesizer is illustrated.

According to the embodiment of the present invention described above, since it is possible to process a multi-band while embedding a voltage-controlled oscillator, it is possible to operate a low-power and multi-band system as one frequency synthesizer.

Since the frequency synthesizer of the present invention can process multiple bands while incorporating a voltage controlled oscillator, it is possible to process low power and multiple bands.

1 is a diagram illustrating a conventional frequency synthesizer.

2 is a diagram illustrating a multi-band frequency synthesizer according to an embodiment of the present invention.

3 is a detailed circuit diagram of the voltage controlled oscillator of FIG.

4 is a diagram showing an example of using a multi-band frequency synthesizer with an oscillator.

Claims (10)

A frequency / phase detector for comparing the reference frequency with the feedback frequency inputted and outputting a comparison result; A charge pump circuit converting the comparison result output from the frequency / phase detector into a current; A low pass filter for generating a voltage corresponding to the current output from the charge pump circuit; A voltage controlled oscillator including a variable capacitor capable of continuous frequency tuning and a switched capacitor capable of discrete frequency tuning, and outputting a voltage control frequency corresponding to the output voltage of the low pass filter; A band selection division circuit for dividing a voltage control frequency of the voltage controlled oscillator by a band selection ratio and outputting a band frequency; And A channel selection division circuit for generating the feedback frequency by dividing the band frequency output from the band selection division circuit by a channel selection ratio. Multiband frequency synthesizer comprising a. The method of claim 1, And a reference frequency generator for receiving an external input frequency and generating the reference frequency required inside the chip. The method of claim 2, And the reference frequency generator outputs a reference frequency by dividing an external input frequency by a predetermined division ratio input and programmed from the outside. delete The method of claim 1, The variable capacitor tunes a fine range of frequencies and the switched capacitor tunes a wide range of frequencies. The method of claim 1, The switched capacitor of the voltage controlled oscillator is a multi-band frequency synthesizer, characterized in that the capacitance is adjusted discretely according to an externally programmed control signal. The method of claim 1, And a band select ratio of the band select divider circuit is adjusted by an externally programmed band select code. The method of claim 1, And the channel selectivity of the channel selector divide circuit is adjusted by an externally programmed channel select code. The method according to any one of claims 1 to 8, The voltage controlled oscillator is a multi-band frequency synthesizer, characterized in that embedded in the multi-band frequency synthesizer. a) comparing a reference frequency with a feedback frequency inputted back, and outputting a current corresponding to the comparison result; b) generating a control voltage corresponding to the current output in step a); c) outputting a voltage control frequency corresponding to the control voltage through a voltage controlled oscillator; d) dividing the voltage control frequency by a band selection ratio and outputting a predetermined band frequency; And e) generating a feedback frequency by dividing the band frequency by a channel selection ratio Multi-band frequency synthesis method comprising a.