KR100478894B1 - Radio Frequency Transmission and Receiving System Using Multi-frequency Sampling - Google Patents

Abstract

The present invention relates to a radio frequency transmission and reception system using multi-frequency multiplication, comprising: a first frequency multiplier (180) for multiplying a resonant frequency to suit a receiving frequency; A transmission / reception switch 190 for switching between the transmission block B and the reception block A by the resonance frequency picked up by the first frequency divider 180; A buffer amplifier 200 for temporarily storing and amplifying the resonant frequency transmitted from the first frequency divider 180 through the transmit / receive switch 190 after being switched to the receiving side by the transmit / receive switch 190; After switching to the transmission side by the transmission and reception switch 190, and includes a second frequency multiplier 210 for sampling the resonant frequency transmitted from the first frequency divider 180 through the transmission and reception switch to match the transmission side frequency In addition, the circuit configuration can be simplified, and the number of crystals that occupy a large portion of the high-frequency module price can be reduced.

Description

Radio Frequency Transmission and Receiving System Using Multi-frequency Sampling

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radio frequency transmission and reception apparatus in a wireless communication system using multiple frequency multiplication, and more particularly, to a radio frequency transmission / reception system capable of transmitting and receiving multiple resonant frequencies.

In general, a radio frequency transmission / reception system refers to a communication device using radio waves, and is composed of a transmission device for transmitting radio waves and a reception device for receiving radio waves.

A device that emits radio waves generates electromagnetic vibrations that can be used to carry the necessary signals, amplify them to a sufficient size, and then radiate them from the transmitting antenna, while attenuating the weak radio waves from the receiving antenna and amplifying them. By extracting and amplifying it and converting it into mechanical vibration, information is obtained and communication by radio waves occurs.

As described above, a transmission / reception system using a radio frequency is divided into a reception block (A) and a transmission block (B) as shown in FIG. 1.

First, the reception block A is a surface acoustic wave filter 3 for filtering a weak radio frequency, that is, a radio wave, received through the antenna 1 to a predetermined bandwidth, and operates in a switching cycle according to a radio frequency reception cycle operated in a time division manner. Low noise amplifier (hereinafter referred to as LNA) 7 which amplifies the radio frequency transmitted from the transmit / receive switch 5, the radio frequency transmitted from the transmit / receive switch 3 to a radio frequency in a low noise state, and transmits from the LNA 7 The amplified radio frequency and the resonant frequency provided from the receiving corrector 15 and the VCO 13 through the frequency divider 11 are mixed by the mixer 9 to generate an intermediate frequency.

Next, in the transmission block B, when the transmission information is transmitted through the Tx data input signal port, the VCD 25 is driven, and the transmission information is transmitted through the driven VCD 25. At this time, the resonant frequency is resonated by the modifier 23 and the transmission VCO 21, and the transmission information is loaded on the resonant frequency collected by the frequency divider 19 and transmitted to the power amplifier 17. The power amplifier 17 power-amplifies the transmission information to a sufficient size and transmits it to the transmission / reception switch 5. The transmission / reception switch 5 radiates power amplified transmission data through the surface acoustic wave filter 3 and the antenna 1.

The transmission block (B) and the reception block (A) configured as described above are radio frequency only when the transmit / receive modifiers 23 and 15 and the transmit / receive VCOs 21 and 13 and the transmit / receive frequency divider 19 and 11 are operated. There was an inefficient problem of transmitting and receiving.

Accordingly, the present invention has been made to solve the above-mentioned inefficient problem, the object of which is to receive a radio frequency as a single frequency multiplication, radio frequency using a multi-frequency multiplication to transmit a radio frequency as a multi-frequency multiplication In providing a transmission and reception system.

In order to achieve the above object, the present invention provides a radio frequency transmission / reception system using multi-frequency multiplication, comprising: a first frequency multiplier for multiplying a resonance frequency to be suitable for a receiving side frequency; A transmission / reception switch for switching between a transmission block and a reception block by a resonance frequency picked up by a first frequency divider; A buffer amplifier for temporarily storing and amplifying the resonance frequency transmitted from the first frequency divider through the transmit / receive switch after being switched to the receiver by the transmit / receive switch; And a second frequency divider configured to switch the resonant frequency transmitted from the first frequency divider through the transmit / receive switch to suit the transmitting side frequency after being switched to the transmitting side by the transmit / receive switch.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration and operation of the present invention.

2 is a circuit diagram of a radio frequency transmission and reception system using multi-frequency sampling according to a preferred embodiment of the present invention, which includes an antenna 100, a SAW filter 110, 2 Tx / Rx switch (120, 190), low noise amplifier (hereinafter referred to as LNA 130), mixer (140), voltage controlled diode (Voltage Controlled Diode) (Hereinafter, abbreviated as VCD) 150, crystal 160, voltage controlled oscillator (hereinafter, abbreviated as VCO) 170, and frequency multiplier 180, 210, a buffer amplifier 200, and a power amplifier 220.

The antenna 100 transmits a weak radio frequency, that is, a radio wave, to the surface acoustic wave filter 110 in the reception block A, and transmits the surface acoustic wave filter 110 in the transmission block B. Emit transmission information transmitted from

The surface acoustic wave filter 110 is a bandpass filter, in which oscillations of surface acoustic waves and intervals between the receiving comb electrodes for one cycle are generated and the vibrations are surface acoustic waves, which propagate to the other comb electrodes. It is output as an electric signal. That is, in the reception block A, if the radio frequency induced from the antenna 100 and the surface acoustic wave generated from the comb electrode are the same, only the radio frequency of the surface acoustic wave frequency band is transmitted through the first transmit / receive switch 120 to the LNA 130. Transmit radio frequency. In the transmission block B, if the radio frequency transmitted from the first transmit / receive switch 120 is equal to the surface acoustic wave generated from the comb-shaped electrode, the radio frequency of the surface acoustic wave frequency band is transmitted to the antenna 100.

The first transmit / receive switch 120 switches between the receiving block A and the transmitting block B, and the first transmit / receive switch 120 in the receiving block A is a radio transmitted from the surface acoustic wave filter 110. Switch to transmit frequency to LNA 130. The first transmit / receive switch 120 in the transmission block B switches to transmit the radio frequency amplified and transmitted from the power amplifier 220 to the surface acoustic wave filter 110.

The LNA 130 transmits the radio frequency amplified to the best state without noise of the weak radio frequency transmitted from the surface acoustic wave filter 110 by the switching of the first transmission / reception switch 120 to the mixer 140.

The mixer 140 mixes a radio frequency amplified and transmitted from the LNA 130 and a reception resonance frequency amplified and transmitted from the buffer amplifier 200.

VCD 150 is a diode that is operated by the control of the voltage, there is a bar cap, a parametric diode and the like. When the VCD 150 reverse biases the diode, the diode serves as a capacitance, which is generated by the minority carrier and the surface leakage current, and resistance in addition to the capacitance is generated. VCD 150 is provided with a tuning voltage (not shown) to generate a transmit capacitance value.

The modifier 160 generates a resonant frequency used in the wireless transmission / reception system by self-correction.

The VCO 170 is an oscillation circuit operated by voltage control, and includes a crystal oscillation circuit, an LC oscillation circuit, an RC multivibrator, and the like. According to the present invention, the crystal oscillation circuit by the crystal 160, and transmits the resonance frequency by the crystal 160 to the first frequency multiplier 180.

The first frequency divider 180 divides the resonant frequency by the VCO 170 into a frequency used in the wireless transmission / reception system, and then transmits the collected radio frequency to the second transmission / reception switch 190.

The second transmit / receive switch 190 switches to transmit the resonant frequency collected by the first frequency multiplier 180 to the second frequency multiplier 210 when transmitting, and to the buffer amplifier 200 when receiving. Switch to transmit.

The buffer amplifier 200 temporarily stores and amplifies the resonance frequency transmitted from the second transmission / reception switch 190, and then transmits the temporarily stored and amplified resonance frequency to the mixer 140.

The second frequency multiplier 210 multiplies the resonant frequency saturated by the first frequency multiplier 180 to suit the transmission frequency, and then transmits the multiply multiplied resonant frequency to the power amplifier 220. .

The power amplifier 220 amplifies the resonant frequency transmitted by multiplexing the second frequency divider 210 and then transmits the amplified radio frequency to the surface acoustic wave filter 110 through the first transmission / reception switch 120. .

A radio frequency transmission / reception system using multi-frequency sampling according to an embodiment of the present invention having the above-described configuration will be described in more detail.

According to the present invention, the reception block A is divided into a transmission block B and transmits and receives a radio frequency. First, the reception block A will be described. When receiving weak information through the antenna 100, The VCD 150 receives a tuning voltage (not shown) and provides a capacitance value to the modifier 160 and the VCO 170. The modifier 160 and the VCO 170 generate a resonant frequency based on the capacitance value and transmit the generated resonant frequency to the first frequency divider 180.

The first frequency divider 180 multiplies the resonant frequency and then transmits the single-reduced resonant frequency to the buffer amplifier 200 through the second transmit / receive switch 190. The buffer amplifier 200 temporarily stores and amplifies the single-drained resonance frequency, and then transmits the temporarily stored and amplified resonance frequency to the mixer 140. At this time, the mixer 140 is transmitted from the antenna 100 through the surface acoustic wave filter 110 and the first transmit / receive switch 120, and the radio frequency amplified by the LNA 130 and the frequency transmitted from the buffer amplifier 200 are collected. The resonant frequencies are mixed to generate an intermediate frequency IF.

Next, the transmission block B will be described. When the transmission information is transmitted through the Tx DATA INPUT signal port, and the tuning voltage is transmitted, the VCD 150 is driven. The driven VCD 150 receives a tuning voltage and provides a capacitance value to the modifier 160 and the VCO 170. The modifier 160 and the VCO 170 generate a resonant frequency according to the capacitance value, and then carry the transmitted information to the first frequency divider 180.

The first frequency multiplier 180 multiplies the resonant frequency and then transmits the single frequency resonated frequency to the second frequency multiplier 210 through the second transmission / reception switch 190. At this time, the second frequency multiplier 210 multiplies the resonant frequency saturated by the first frequency multiplier 180 to suit the transmission frequency, and then transfers the multiplied multiply resonant frequency to the power amplifier 220. send.

The power amplifier 220 amplifies the resonance frequency to a sufficient magnitude and transmits the power to the first transmission / reception switch 120. The first transmission / reception switch 120 radiates the power amplified resonance frequency through the surface acoustic wave filter 3 and the antenna 1.

In this way, in order to drive the transmission and reception blocks (B, A), the resonant frequency is generated only by the transmitting side VCD 150 and the modifier 160, and then the radio frequency is received by the single first frequency divider 180 using the resonant frequency. In addition, the radio frequency may be transmitted by the multiple second frequency divider 210.

According to the present invention as described above, by receiving the radio frequency by the single frequency divider by the resonant frequency of the voltage control diode and the crystal, and by transmitting the radio frequency by the multi-frequency divider, the configuration of the circuit is simplified, high frequency This can reduce the number of modifiers that make up a significant portion of the module price.

1 is a circuit diagram of a conventional radio frequency transmission and reception system using a single frequency sampling,

2 is a circuit diagram of a radio frequency transmission and reception system using multiple frequency grading according to the present invention.

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

100: antenna 110: surface acoustic wave filter (SAW FILTER)

120: first transmit / receive switch (Tx / Rx SW) 130: low noise amplifier (LNA)

140: MIXER 150: voltage control diode (VCD)

160: CRYSTAL 170: voltage controlled oscillator (VCO)

180: first frequency divider (XM) 190: second transmission and reception switch

200: buffer amplifier 210: second frequency multiplier

220: power amplifier (PA)

Claims (1)

After the weak radio frequency is induced from the antenna, the receiving block amplifies and extracts the original information, and an electric vibration of the transmitting side resonant frequency is carried out. In the radio frequency transmission and reception system having a transmission block for radiating by A first frequency multiplier that multiplies the resonant frequency to suit a receiving frequency; A transmission / reception switch for switching between the transmission block and the reception block by a resonance frequency that is picked up by the first frequency divider; A buffer amplifier configured to temporarily store and amplify the resonant frequency transmitted from the first frequency divider through the transmit / receive switch after being switched to the receiver by the transmit / receive switch; And a second frequency divider configured to switch the resonant frequency transmitted from the first frequency divider through the transmit / receive switch to be suitable for the transmit side frequency after being switched to the transmit side by the transmit / receive switch. Radio frequency transmission and reception system using frequency grading.