KR100441266B1 - Circuit for oscillating local frequency in wireless subscribe network system, especially generating 170 mhz local frequency - Google Patents

Abstract

PURPOSE: A circuit for oscillating a local frequency in a wireless subscribe network system is provided to reduce the cost of frequency up-converter by generating 170 MHz local frequency through a logic circuit employing a divider and a counter. CONSTITUTION: A circuit for oscillating a local frequency in a wireless subscribe network system includes a first oscillator(20), a controller(10), a second oscillator(40), a first mixer(30) and a second mixer(50). The first oscillator is provided with a serial/parallel converter(15), a first to a third counter(11,13,14) and a divider(12). The circuit is characterized in that it generates 170 MHz local frequency by dividing the 2060 ¯2090 MHz of local frequency outputted from the second oscillator in response to the dividing ratio by various dividing ratios. In the second mixer, 310MHz from the first mixer and 2060 ¯2090 are mixed to output UHF 2370 ¯2400MHz.

Description

Local Frequency Oscillation Circuit in Wireless Subscriber Network System

The present invention relates to a frequency upconverter of a base station of a wireless local loop (WLL) system, by generating a 170 MHz local oscillation frequency signal using a simple logic circuit to generate an intermediate frequency of 140 MHz of a forward link. (Intermediate Frequency; hereinafter referred to as 'IF') A local frequency oscillator circuit in a WLL system capable of upconverting a signal to a signal in the 2.37 to 2.40 GHz band.

In general, the WLL system is a technology for constructing a telephone line using a wireless system instead of a wired line connecting a telephone subscriber's premises to a subscriber's home. A subscriber access device means a subscriber terminal for configuring a wireless link. And a base station for establishing a wireless link with the subscriber access device by wire connection with a telephone station, a base station controller and a switching station for controlling the base station.

On the other hand, the base station of the WLL system of the above configuration is provided with a frequency up-converter for up-converting the 140MHz IF signal of the forward link to the UHF signal of the 2.37 ~ 2.40GHz band.

In the conventional frequency up-converter, as shown in FIG. 1, when the first oscillator 1 inputs fixed channel-related data from the control unit 1 and generates a local frequency signal of 170 MHz, the first mixer 3 receives 1. Next, a frequency signal of 310 MHz is output by mixing an IF signal of 140 MHz and a local frequency signal of 170 MHz.

Subsequently, when the second oscillator 4 inputs variable channel-related data from the controller 1 and outputs a local frequency signal of 2060 to 2090 MHz, the second mixer 5 secondaryly performs the first mixer 3. A frequency signal of 310 MHz and a local frequency signal of 2060 to 2090 MHz are mixed to output a UHF signal of 2370 to 2400 MHz.

In this case, the first oscillator 2 and the second oscillator 4 are configured to receive both the reference signal and the control data output from the control unit 1, respectively, the local frequency signal of 170MHz and the local frequency signal of 2060-2090MHz There is a PLL circuit for generating the circuit.

However, as described above, the PLL circuits provided in the first oscillator 2 and the second oscillator 4 are quite expensive, thereby increasing the price of the entire system.

The present invention has been made to solve the above problems, the object of which is to divide the local frequency signal of 2060 ~ 2090MHz output from the second oscillator through a low-cost logic circuit consisting of a counter and a divider circuit by local frequency of 170MHz It is to provide a local frequency oscillator circuit in a WLL system that can reduce the price of the frequency up converter as well as the price of the entire system by implementing a first oscillator that generates a signal.

The local frequency oscillation circuit in the WLL system of the present invention for achieving this object is composed of a counter, a divider, and a serial / parallel converter, and each of the 2060 to 2020 outputs from the second oscillator according to the division ratio control signal of the controller. By dividing the local frequency signal of 2090MHz with different division ratios, it is possible to generate the final 170MHz local frequency signal.

1 is a local frequency oscillation circuit diagram of a frequency upconverter of a conventional wireless subscriber network system;

2 is a local frequency oscillation circuit diagram of a frequency up-converter in a wireless subscriber network system according to the present invention.

<Description of the symbols for the main parts of the drawings>

10 control unit 20 first oscillator

30: first mixer 40: second oscillator

50: second mixer

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration and operation of the local frequency oscillation circuit in the WLL system according to the present invention.

FIG. 2 is a local frequency oscillation circuit diagram of a frequency up-converter in a WLL system according to the present invention, and includes a control unit 10 for outputting control signals having different division ratios, and a control signal output from the control unit 10. Therefore, by mixing a local frequency signal of 2060 to 2090 MHz to generate a local frequency signal of 170 MHz, the first oscillator 10 and a 170 MHz local frequency signal output from the first oscillator 10 and an IF signal of 140 MHz are mixed. A first mixer 30 for outputting a frequency signal of 310 MHz, a second oscillator 40 for inputting variable channel data output from the controller 10 to generate a local frequency signal of 2060 to 2090 MHz, and the first 2nd mixer 50 which mixes the local frequency signal of 2060-2090MHz output from the 2 oscillator 40, and the 310MHz frequency signal output from the said 1st mixer 30, and outputs the 2370-2400MHz UHF signal. It is configured.

The first oscillator 20 calculates 2060 to 209 MHz local frequency signals output from the second oscillator 40 to control the Ack signals for three frequencies 2065, 2075, and 2085 MHz. The first counter 11 and the second oscillator 40 output 2060 to 2090 MHz local frequency signals at different frequency division ratios for each of the three frequencies 2065, 2075 and 2085 MHz. A second counter 13 which outputs a 170 MHz local frequency signal by counting the divider 12 and the signals divided and output from the divider 12 according to different reference values according to control signals of the controller 10. And a third counter 14, and a serial / parallel converter 15 for converting serial data output from the control unit 10 into parallel data.

The operation of the local frequency oscillation circuit in the frequency upconverter of the present invention configured as described above is as follows.

First, the second oscillator 40 inputs variable channel related data from the controller 10 to generate a local frequency signal of 2060 to 2090 MHz through the PLL circuit.

At the same time, the first oscillator 20 implemented as a logic circuit inputs a local frequency signal of 2060 to 2090 MHz output from the second oscillator 40 to generate a 170 MHz local frequency signal.

That is, the first counter 11 in the first oscillator 20 calculates a local frequency signal of 2060 to 2090 MHz output from the second oscillator 40 to each of three frequency signals of 2065, 2075, and 2085 MHz. The ACK signal is output to the controller 10.

In this case, three frequency signals of 2065, 2075, and 2085 MHz are generated in the second oscillator 40. Accordingly, in the first oscillator 20 according to the present invention, the division ratio of the frequency divider 12 may be controlled by the respective ax signals so that the same 170 MHz frequency signals may be output for the three frequency signals. The reference value of the second counter 13 and the third counter 14 is also different according to the control signal of.

Subsequently, the divider control signal and the counter reference value are transferred to the divider 12, the second counter 13, and the third counter 14 through the serial / parallel converter 15. )

Accordingly, the divider 12 divides each of three frequencies of 2065, 2075, and 2085 MHz output from the second oscillator using different division ratios, and the second counter 13 and the third counter 14 are divided. The counting values output from the divider 12 are counted, respectively, to output a local frequency signal of 170 MHz from the final second counter 13.

Subsequently, the first mixer 30 mixes the 140 MHz signal and the 170 MHz local frequency signal generated by the first oscillator 20 to output a 310 MHz frequency signal, and then the 310 MHz frequency through the second mixer 50. The signal is mixed with a 2060 to 2090 MHz local frequency signal to output a final 2370 to 2400 MHz UHF signal.

As described above, the frequency upconverter converts the frequency of the 140MHz IF signal into a signal of 2370-2400MHz.

As described above, the present invention can lower the price of the frequency upconverter as well as reduce the cost of the entire system by generating a local frequency of 170 MHz through a logic circuit using a low-cost divider and a counter. It is effective to be.

Claims (1)

The first oscillator 20 generates a 170 MHz local frequency signal according to the control signal output from the control unit 10, and the 170 MHz local frequency signal generated by the first oscillator 20 and the IF signal of 140 MHz mixed together. A first mixer 30 for outputting a frequency signal of 310 MHz, a second oscillator 40 for generating a local frequency signal of 2060 to 2090 MHz in accordance with a control signal output from the controller 10, and the second oscillator 40 In the frequency up-converter consisting of a second mixer 50 for outputting a UHF signal of 2370 ~ 2400MHz by mixing a local frequency signal of 2060 ~ 2090MHz output from the) and 310MHz frequency signal output from the first mixer 30 In The first oscillator 20 calculates a 2060 to 2090 MHz local frequency signal output from the second oscillator 40 and outputs an ack signal for each 2065, 2075, 2085 MHz frequency signal to the controller 10. A frequency divider 12 for dividing the 2060 to 2090 MHz local frequency signal output from the second oscillator 40 with different division ratios for the respective 2065, 2075, and 2085 MHz frequency signals; The second counter 13 and the third counter 14 for counting the signals divided and output from the divider 12 according to control signals of the controller 10 and outputting 170 MHz local frequency signals, respectively. And a serial / parallel converter (15) for converting serial data output from the control unit (10) into parallel data.

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