KR101312142B1 - Apparatus and method for transmitting and receiving signal in a communication system - Google Patents

Abstract

The present invention provides a signal transmission and reception device in a communication system, comprising: an amplifier for amplifying a transmission signal power, a bias controller for controlling an operation of the amplifier, a bias controller for applying the generated bias, a frequency division duplexing scheme or Receives a duplexing scheme selection signal corresponding to a time division duplexing scheme and a transmission / reception operation signal corresponding to a signal transmission / reception operation of the time division duplexing scheme, and receives the bias using the duplexing scheme selection signal and the transmission / reception operation signal. It includes a power amplification control unit for controlling the operation of the control unit.

Power Amplifiers, High Power Amplifiers, Bias, Time Division Duplexing, Frequency Division Duplexing

Description

A device and method for transmitting and receiving signals in a communication system {APPARATUS AND METHOD FOR TRANSMITTING AND RECEIVING SIGNAL IN A COMMUNICATION SYSTEM}

1 is a view schematically showing a structure of a signal transmission and reception apparatus using a frequency division duplexing scheme in a general wireless communication system;

2 is a diagram schematically illustrating a structure of a signal transmission and reception apparatus using a time division duplexing scheme in a general wireless communication system;

3 is a diagram schematically illustrating a structure of a signal transmission and reception apparatus simultaneously supporting a frequency / time division duplexing scheme in a communication system according to an embodiment of the present invention;

4 is a view schematically illustrating an operation according to a frequency division duplexing method in a signal transmission / reception apparatus which simultaneously supports a frequency / time division duplexing scheme according to an embodiment of the present invention;

FIG. 5 is a diagram schematically illustrating an operation according to a time division duplexing method in a signal transmission / reception apparatus which simultaneously supports a frequency / time division duplexing scheme according to an embodiment of the present invention. FIG.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a communication system, and more particularly, to an apparatus and method for transmitting and receiving a signal that simultaneously applies a time division duplexing (TDD) and a frequency division duplexing (FDD) scheme in a communication system. .

In general, a wireless communication system uses a duplexing scheme, and such a duplexing scheme divides frequency uplinking uplink (UL) and downlink (DL) downlink based on frequency. It is divided into a duplexing scheme and a time division duplexing scheme for duplexing uplink and downlink transmissions based on time.

The frequency division duplexing scheme is a scheme in which uplink and downlink are duplexed using different frequencies, and a structure of a transmission / reception apparatus using the frequency division duplexing scheme will be described with reference to FIG. 1.

1 is a diagram schematically illustrating a structure of a signal transmission and reception apparatus using a frequency division duplexing scheme in a general wireless communication system.

Referring to FIG. 1, a signal transceiving device using a frequency division duplexing scheme includes a transmitter 111, a high power amplifier 113, a duplexer 119, and a low noise amplifier. (LNA: Low Noise Amplifier) 121 and a receiver 123.

The signal transceiving apparatus using the frequency division duplexing scheme may be divided into a transmitter for transmitting a signal and a receiver for receiving a signal, and the transmitter includes the transmitter 111 and the high power amplifier 113. The receiver includes the low noise amplifier 121 and the receiver 123.

The high power amplifier 113 is included in a transmission unit for transmitting the signal, and receives signals from the baseband performing radio processing. The high power amplifier 113 includes a drive amplifier (DA) 115 and a main amplifier 117, and the high power amplifier 113 has sufficient power at the end of the signals. Amplify the signal power so that it can.

The low noise amplifier 121 is included in a receiver for receiving the signal and receives a signal received through an antenna. In this case, the low noise amplifier 121 enables the signal to be amplified while suppressing the amplification of the noise of the received signals in which the noise on the wireless channel is mixed. The receiver 123 performs radio processing on the output signal of the low noise amplifier 121 to restore the received signal.

The duplexer 119 serves to branch a transmission signal and a reception signal while using one antenna together with a transmitter and a receiver. The duplexer 119 may include a transmission band pass filter (BPF) and a reception band pass filter which serve to distinguish different transmission and reception frequency bands according to transmission and reception.

In addition, the time division duplexing scheme is a duplexing scheme using time. Therefore, when using the time division duplexing scheme, since the frequencies of the uplink and the downlink are the same, the uplink time interval for transmitting the uplink signal and the downlink time interval for transmitting the downlink signal are previously separated. Only an uplink signal is transmitted in the uplink time period and only a downlink signal is transmitted in the downlink time period. Next, a structure of a signal transmission and reception apparatus using the time division duplexing scheme will be described with reference to FIG. 2.

2 is a diagram schematically illustrating a structure of a signal transmission and reception apparatus using a time division duplexing scheme in a general wireless communication system.

Referring to FIG. 2, the signal transmission / reception apparatus using the time division duplexing scheme includes a transmitter 211, a high power amplifier 213, a switch 219, a band pass filter 221, a low noise amplifier 223, and a receiver. 225.

The signal transceiving apparatus using the time division duplexing scheme may be divided into a transmitter for transmitting a signal and a receiver for receiving a signal, wherein the transmitter includes the transmitter 211 and the high power amplifier 213. The receiver includes the low noise amplifier 223 and the receiver 225.

The high power amplifier 213 is included in a transmitter for transmitting the signal, and receives signals from the baseband that perform radio processing. The high power amplifier 213 may include a drive amplifier (DA) 215 and a main amplifier 217, and the high power amplifier 213 may have sufficient power at the end of the signals. Amplify the signal power so that it can.

The low noise amplifier 223 is included in a receiver for receiving the signal and receives a signal received through an antenna. In this case, the low noise amplifier 223 enables the signal to be amplified while suppressing amplification of the noise of the received signals in which the noise on the wireless channel is mixed. The receiver 225 restores the received signal by performing radio processing on the output signal of the low noise amplifier 223.

The band pass filter 221 filters the signal to be transmitted by the transmitter and the signal of the transmission frequency band to be correctly transmitted through the antenna, and the signal to be received and the signal of the reception frequency band among the signals received through the antenna. Filter to receive correctly. The time division duplexing transceiver uses the same frequency band, and thus has the advantage of transmitting and receiving signals using the band pass filter 221.

The switch 219 switches the signal of the transmitter to be transmitted through the antenna when performing a signal transmission operation according to the time division duplexing scheme, and switches the signal of the antenna when the signal reception operation is performed. Switch to the receiver.

As described above, the time division duplexing scheme and the frequency division duplexing scheme have a difference in structure of each transceiver for transmitting and receiving signals. In addition, in order to perform communication between signal transceivers using the time division duplexing scheme and the frequency division duplexing scheme, communication is possible only when the hardware structure of each signal transceiver is changed. Accordingly, the time division duplexing scheme and the frequency division duplexing scheme are simultaneously supported, that is, mixed, by using the signal transceiver using the time division duplexing scheme and the signal transceiver using the frequency division duplexing scheme. There was this.

In addition, the frequency division duplexing method uses different frequencies for signal transmission and reception. Therefore, the signal transceiver using the frequency duplexing method transmits and receives the signal independently of the transmitter and the receiver, so that the high power amplifier continuously operates. However, the time division duplexing method transmits and receives a signal through different time periods for signal transmission and reception so that transmission and reception of signals are alternately performed, and thus continuous operation of the high power amplifier is impossible. Therefore, in order to simultaneously support the time division duplexing scheme and the frequency division duplexing scheme, there is a problem in that an amplifier corresponding to each duplexing scheme, that is, a high power amplifier must be separately provided.

Accordingly, an object of the present invention is to provide an apparatus and method for transmitting and receiving signals simultaneously supporting a time division duplexing scheme and a frequency division duplexing scheme in a communication system.

Another object of the present invention is to provide an apparatus and method for transmitting and receiving a signal using a high power amplifier that simultaneously supports a time division duplexing scheme and a frequency division duplexing scheme in a communication system.

The apparatus of the present invention is a signal transmission and reception apparatus in a communication system, comprising: an amplifier for amplifying a transmission signal power, a bias controller for generating a bias for controlling an operation of the amplifier, and applying the generated bias, and a frequency division duple. Receives a duplexing method selection signal corresponding to a lexing method or a time division duplexing method and a transmission / reception operation signal corresponding to a signal transmission / reception operation of the time division duplexing method, and uses the duplexing method selection signal and the transmission / reception operation signal. And a power amplification controller for controlling the operation of the bias controller.

According to another aspect of the present invention, in a signal transmission and reception apparatus in a communication system, a duplexing scheme used for signal transmission and reception is selected from a time division duplexing scheme and a frequency division duplexing scheme, and a duplexing scheme corresponding to the selected duplexing scheme is provided. A system control unit for generating a scheme selection signal, a bias for receiving the duplexing scheme selection signal, and controlling a bias to control at least one amplifier according to the received duplexing scheme selection signal, and using the generated bias It includes a power amplifier for controlling at least one amplifier.

In the method of transmitting and receiving a signal in a communication system, a method of determining a duplexing method used for transmitting and receiving a signal among a time division duplexing scheme and a frequency division duplexing scheme, and transmitting according to the determined duplexing scheme And generating a bias for controlling the operation of the amplifier for amplifying the signal power, and controlling the amplifier through the generated bias.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description, only parts necessary for understanding the operation according to the present invention will be described, and the description of other parts will be omitted so as not to obscure the gist of the present invention.

The present invention proposes a signal transmission / reception apparatus and method that simultaneously support, that is, use, a time division duplexing (TDD) and a frequency division duplexing (FDD) scheme in a communication system. According to the present invention, the time division duplexing scheme and the frequency division duplex are controlled by applying a bias to a power amplifier, for example, a high power amplifier (HPA) corresponding to the time division duplexing scheme and the frequency division duplexing scheme. The present invention proposes a signal transmission / reception apparatus and method for simultaneously supporting a lexing scheme. In addition, a signal transmitting and receiving device and method for configuring a switch in the signal input path of the low noise amplifier according to the time division duplexing scheme and the frequency division duplexing scheme, and switching control of the signal received through the antenna through the switch Suggest. Next, a structure of a signal transmission and reception apparatus which simultaneously supports the time division duplexing scheme and the frequency division duplexing scheme will be described with reference to FIG. 3.

3 is a diagram schematically illustrating a structure of a signal transmission and reception apparatus simultaneously supporting a frequency / time division duplexing scheme in a communication system according to an embodiment of the present invention.

Referring to FIG. 3, the signal transmission and reception apparatus of the present invention supports both a frequency division duplexing scheme and a time division duplexing scheme, and the signal transmission and reception apparatus includes a transmitter 311 and a high power amplifier (HPA). An amplifier (315), a circulator (325), a band pass filter (BPF) 327, a switch (329), a low noise amplifier (LNA) 331, A receiver 333 is included.

The signal transceiving apparatus may support both a frequency division duplexing scheme and a time division duplexing scheme, and may be classified into a transmitter for transmitting a signal and a receiver for receiving a signal. 311 and a high power amplifier 315, that is, a power amplifier, and the receiver includes the low noise amplifier 331 and the receiver 333.

The high power amplifier 315 is included in a transmitter for transmitting the signal, and receives signals from the baseband that perform radio processing. The high power amplifier 315 includes a drive amplifier (DA) 321, a main amplifier (MA) 323, a power amplifier controller 317, and a bias controller. 319.

The transmitter 311 generates a baseband signal to be transmitted through an antenna and outputs the baseband signal to the high power amplifier 315.

The high power amplifier 315 functions to amplify the power so that the signals have sufficient power at the final stage. In many cases, the main amplifier 323 included in the high power amplifier 315 does not have sufficient gain in structure, and the main amplifier 323 is fixed to the main amplifier 323 in order to amplify with sufficient power. The power of magnitude should be output. Accordingly, the driving amplifier 321 solves the shortage of the gain of the main amplifier 323, and simultaneously generates sufficient input power to the main amplifier 323 and outputs it to the main amplifier 323.

The main amplifier 323 functions to amplify the power so that the signal received from the driving amplifier 321 can be output as a signal having sufficient power at the final stage. This allows the signal to be amplified with gain, but unlike other amplifiers, it is designed to allow a large amount of current to flow at the output, enabling the use of high dBm of power at the output. The main amplifier 323 may also be referred to as a power amplifier (PA) as an example. In addition, the driving amplifier 321 and the main amplifier 323 correct the gain.

The signal transmission and reception apparatus of the present invention includes a system controller (not shown) for controlling the signal transmission and reception apparatus. Accordingly, the system controller selects a duplexing scheme used in the signal transmission / reception apparatus, for example, time division duplexing and frequency division duplexing. Thus, the system controller generates a duplex mode selection signal corresponding to the selected duplexing scheme. Accordingly, the power amplifier 315 may identify the duplexing scheme currently used in the signal transmission / reception apparatus through the duplexing scheme selection signal.

When the duplexing scheme is a time division duplexing scheme, the system controller generates a transmission / reception operation signal (Tx / Rx motion signal) according to a signal transmission operation or a signal reception operation of the signal transmission / reception apparatus. Accordingly, the power amplifier 315 may check whether the signal transmission operation or the signal reception operation of the time division duplexing method is performed through the transmission / reception operation signal.

The high power amplifier 315 receives the duplexing method selection signal or the transmission / reception operation signal from a system control unit (not shown) existing in the signal transmission / reception apparatus of the present invention to receive the amplifiers, that is, the driving amplifier 321. And the main amplifier 323.

The power amplification control unit 317 of the high power amplifier 315 receives the duplexing mode selection signal or the transmission / reception operation signal, and uses a control signal to control the operation of the bias control unit 319 using the received signal. Create Here, the power amplification control unit 317 controls the bias control unit 319 through the generated control signal.

The bias controller 319 generates a bias for controlling the operation of the driving amplifier 321 and the main amplifier 323 through the control of the power amplification controller 317, and applies the generated bias to drive the driving. The operation of the amplifier 321 and the main amplifier 323 is controlled. For example, the bias may be a bias voltage or a bias current, and the bias input to each amplifier, that is, Vgs may have the same value for each amplifier or may have a different value for each amplifier. Here, the bias control unit 319 generates the bias using a DC power supplied from the power supply 313. When the bias is applied, the driving amplifier 321 and the main amplifier 323 perform an operation of amplifying signal power, that is, an ON operation. If the bias is not applied, the driving amplifier 321 is applied. The main amplifier 323 performs an operation of not amplifying the signal power, that is, an OFF operation. The bias control unit 319 may be included in the power amplification control unit 317. The operation of the high power amplifier 315 corresponding to each duplexing scheme will be described in detail with reference to FIGS. 4 and 5 below.

The circulator 325 is a directional device, and transmits the signal output from the high power amplifier 315 of the transmitter through the band pass filter 327 through an antenna, and the signal received through the antenna is The low power amplifier 331 is received through the band pass filter 327.

The band pass filter 327 filters the signal to be transmitted by the transmitter and the signal of the transmission frequency band to be correctly transmitted through the antenna, and the signal to be received and the signal of the reception frequency band among the signals received through the antenna. Filter to receive correctly. In the case of using the frequency division duplexing scheme, a band pass filter capable of filtering both a transmission frequency band and a reception frequency band may be used, and at least one band pass filter may be used to filter each transmission / reception frequency band. In the case of using the time division duplexing scheme, a band pass filter is used to transmit and receive a signal as the same frequency band is used for transmission and reception.

The low noise amplifier 331 is included in a receiver for receiving the signal and receives a signal received through an antenna. In this case, the low noise amplifier 331 allows the signal to be amplified while suppressing the amplification of the received signals that are mixed with noise on the wireless channel. The receiver 333 performs radio processing on the output signal of the low noise amplifier 331 so that the receiver recovers the received signal.

The switch 329 switches a signal received through the antenna between the circulator 325 and the low noise amplifier 331 through an on / off operation. The on / off operation of the switch 329 blocks noise signal components flowing into the low noise amplifier 331 to improve reception sensitivity and protect the circuit of the low noise amplifier 331. Therefore, when the switch 329 is turned on, the signal received through the antenna is input to the low noise amplifier 331, and when the switch 329 is turned off, the signal input is cut off to the low noise amplifier 331. do.

In addition, the system controller generates a switch control signal for controlling the switch 329, for example, an ON / OFF signal according to the duplexing scheme and the signal transmission / reception operation, and generates the switch control signal. Is used to control the switch 329.

Next, the signal transmission and reception apparatus in the case of using the frequency division duplexing scheme will be described below with reference to FIG. 4.

4 is a diagram schematically illustrating an operation according to a frequency division duplexing method in a signal transmission / reception apparatus which simultaneously supports a frequency / time division duplexing scheme according to an embodiment of the present invention.

Referring to FIG. 4, since the signal transceiver shown in FIG. 4 has the same structure as the signal transceiver shown in FIG. 3, a detailed description of the signal transceiver will be made with reference to FIG. 3. The detailed description thereof will be omitted. Accordingly, it is assumed that the apparatus for transmitting and receiving a signal of FIG. 4 operates in a frequency division duplexing scheme.

The system controller (not shown) selects a frequency division duplexing scheme when the signal transmission / reception apparatus uses a frequency division duplexing scheme. The system controller generates a duplexing scheme selection signal indicating that the duplexing scheme currently used by the signal transmission and reception apparatus is the frequency division duplexing scheme. The generated duplexing scheme selection signal is output to the high power amplifier 315.

The power amplification control unit 317 of the high power amplifier 315 receives the duplexing scheme selection signal, and the duplexing scheme currently used in the signal transmission / reception apparatus through the duplexing scheme selection signal is a frequency division duplexing scheme. It is possible to confirm. The high power amplifier 315 controls the bias control unit 319 to control signal power amplification of the amplifiers, that is, the driving amplifier 321 and the main amplifier 323. That is, the power amplification control unit 317 is a bias setting value for generating the bias applied to the driving amplifier 321 and the main amplifier 323 for controlling the power of the power amplification control unit 317, that is, Vgs_drive, Vgs_main Determine. In this case, Vgs_drive is a bias setting value for bias generation of the driving amplifier 321, and Vgs_main is a bias setting value for bias generation of the main amplifier 323. The power amplification control unit 317 outputs the bias setting values to the bias control unit 319. The bias set point is a bias set point at which the amplifiers amplify the signal power, that is, the amplifiers are turned on.

The bias control unit 319 receives the determined bias setting values, Vgs_drive and Vgs_main through the power amplification control unit 317. The bias control unit 319 generates a bias corresponding to the received bias setting value. The bias control unit 319 is supplied with DC power through the power supply 313 and set according to the bias setting value, and then applies a bias to each of the amplifiers, the driving amplifier 321 and the main amplifier 323. do. In this case, the bias applied may be a gate bias, for example, and a bias applied to each amplifier may be different or equal to each amplifier. Accordingly, the amplifiers amplify the signal power transmitted from the signal transceiver.

In addition, since the frequency division duplexing method is duplexed using different frequencies for transmitting and receiving signals, different frequencies are used for transmitting and receiving signals. Accordingly, the system control unit controls the switch 329 to be turned on to generate a switch control signal, for example, an on signal, so that the received signal of the antenna is input to the low noise amplifier 331, and the generated switch control signal is Output to switch 329.

The switch 329 receives the switch control signal and switches the signal received through the antenna, that is, the output signal of the circulator 325 to the low noise amplifier 331. In other words, when the signal transmission and reception apparatus operates in the frequency division duplexing scheme, the switch 329 receives the switch control signal and outputs the signal received through the antenna to the low noise amplifier 331.

Signal flows according to signal transmission and signal reception of the signal transmission and reception apparatus are shown as A and B in FIG. 4. That is, when the frequency division duplexing method is used, transmission and reception of a signal, that is, A and B communicate using different frequencies, so it is possible to independently transmit and receive a signal, and the high power amplifier 315 is an input signal. Amplify the power. Therefore, the Vgs signal applies a bias to operate the amplifiers, that is, the driving amplifier 321 and the main amplifier 323, and the switch 329 is turned on. Hereinafter, the signal transmission and reception apparatus in the case of using the time division duplexing scheme will be described with reference to FIG. 5.

FIG. 5 is a diagram schematically illustrating an operation according to a time division duplexing method in a signal transmission / reception apparatus which simultaneously supports a frequency / time division duplexing method according to an embodiment of the present invention.

Referring to FIG. 5, since the signal transceiver shown in FIG. 5 has the same structure as the signal transceiver shown in FIG. 3, a detailed description of the signal transceiver is referred to FIG. 3. The detailed description thereof will be omitted. Accordingly, it is assumed that the apparatus for transmitting and receiving a signal of FIG. 5 operates in a time division duplexing scheme.

The system controller (not shown) selects a time division duplexing scheme if the signal transmission / reception apparatus uses a time division duplexing scheme. The system controller generates a duplexing scheme selection signal indicating that the duplexing scheme currently used by the signal transmission and reception apparatus is the time division duplexing scheme. The system controller determines whether the current signal transmission / reception operation is a signal transmission operation or a signal reception operation of the time division duplexing method, and generates a transmission / reception operation signal indicating a signal transmission / reception method according to the determination result. The generated duplexing method selection signal and the transmission / reception operation signal are output to the high power amplifier 315.

The system control unit may generally refer to the signal transceiving operation signal as a transistor transistor logic (TTL) signal or a low voltage transistor transistor logic (LVTTL). Signal). However, when the distance from the high power amplifier is far, the signal is converted into a low voltage differential signaling (LVDS) signal and then transmitted. The reason for this is that the LVDS signal can be recovered without error even if the signal is stronger to external noise or weaker than the LVTTL signal. The system controller may use at least one of a TTL signal, an LVTTL signal, and an LVDS signal as the signal transmission / reception signal.

The power amplification control unit 317 of the high power amplifier 315 receives the duplexing method selection signal and the transmission / reception operation signal. In addition, it is possible to confirm that the duplexing scheme currently used in the signal transmission / reception apparatus is a time division duplexing scheme through the duplexing scheme selection signal. In addition, it is possible to check whether the signal transmission / reception apparatus currently performs a signal transmission operation or a signal reception operation through the transmission / reception operation signal.

The high power amplifier 315 controls the bias control unit 319 to control signal power amplification of the amplifiers, that is, the driving amplifier 321 and the main amplifier 323. That is, the power amplification control unit 317 is a bias setting value for generating the bias applied to the driving amplifier 321 and the main amplifier 323 for controlling the power of the power amplification control unit 317, that is, Vgs_drive, Vgs_main Determine. In this case, Vgs_drive is a bias setting value for bias generation of the driving amplifier 321, and Vgs_main is a bias setting value for bias generation of the main amplifier 323. The power amplification control unit 317 outputs the bias setting values to the bias control unit 319.

In this case, the power amplification control unit 317 outputs signal power amplification, that is, a bias setting value in which the amplifiers are on, when performing the time division duplexing signal transmission operation (C of FIG. 5). However, the power amplification control unit 317 does not perform signal power amplification when the time division duplexing signal receiving operation (D in FIG. Outputs

The bias control unit 319 receives the determined bias setting value, Vgs_drive or Vgs_main through the power amplification control unit 317. The bias control unit 319 generates a bias corresponding to the received bias setting value. The bias control unit 319 is supplied with DC power through the power supply 313 and set according to the bias setting value, and then applies a bias to each of the amplifiers, the driving amplifier 321 and the main amplifier 323. do. Here, the bias applied may be a gate bias, for example, and the bias applied to each amplifier may be different or the same value for each amplifier. Therefore, the amplifiers do not amplify or amplify the signal power transmitted from the signal transmission and reception device. Accordingly, the bias control unit applies a bias for power amplification of the amplifiers in the time division duplexing signal transmission operation. In the time division duplexing signal reception operation, a bias is applied to prevent the amplifiers from amplifying the power, that is, the bias is not applied.

In addition, since the frequency division duplexing method uses a different time for transmitting and receiving a signal, time intervals for transmitting and receiving signals are different from each other. Accordingly, the system controller controls the switch 329 to turn on / off a signal according to a signal transmission / reception operation.

In response to the time division duplexing signal transmission operation, the system controller generates a switch control signal, for example, an off signal so that the received signal of the antenna is not input to the low noise amplifier 331, and generates the switch control signal. Output to the switch 329. In addition, the system controller generates a switch control signal, for example, an ON signal so that the received signal of the antenna is input to the low noise amplifier 331 when the signal division operation of the time division duplexing method is performed, and generates the generated switch control signal. Output to the switch 329.

The switch 329 receives the switch control signal and does not switch the signal received through the antenna, that is, the output signal of the circulator 325 to the low noise amplifier 331. In other words, the switch 329 receives the switch control signal (for example, an on signal) when the signal transmission / reception device transmits the signal of the time division duplexing method, and converts the signal received through the antenna into a low noise amplifier ( 331). However, when the signal transmission / reception device receives a signal of the time division duplexing method, the switch 329 receives the switch control signal (for example, an off signal) to receive a signal received through the antenna to a low noise amplifier 331. Do not print

Signal flows according to signal transmission and signal reception of the signal transmission and reception apparatus are shown as C and D in FIG. That is, when the time division duplexing method is used, different time periods are used for signal transmission and reception, that is, C and D communicate using different times. Therefore, the high power amplifier 315 performs an amplification operation according to a signal transmission / reception scheme with respect to the input signal power. Accordingly, in the signal transmission operation, the Vgs signal applies a bias to operate the amplifiers, that is, the driving amplifier 331 and the main amplifier 323, and the switch 329 performs an off operation. However, in the signal reception operation, the Vgs signal does not apply a bias so that the amplifiers, that is, the driving amplifier 331 and the main amplifier 323 do not operate, and the switch 329 operates on. When the signal transceiving device uses the time division duplexing scheme, the power amplifier 315 and the switch 323 alternately operate, that is, on and off operations.

In the present invention, signal transmission and reception operations according to the frequency division duplexing scheme and the time division duplexing scheme have been described. In this case, the switch is controlled by the system controller, but the switch may be designed to control the switch through the power amplification controller of the power amplifier.

Therefore, in the present invention, a signal transmission / reception scheme is simultaneously applied using one high power amplifier without separately providing an amplifier corresponding to each duplexing, that is, a high power amplifier. In addition, in the time division duplexing scheme, overall power consumption of the system is reduced by amplifying signal power through bias application. In addition, a switch is further configured to protect the low noise amplifier and the receiver.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments, but is capable of various modifications within the scope of the invention. Therefore, the scope of the present invention should not be limited by the illustrated embodiments, but should be determined by the scope of the appended claims and equivalents thereof.

As described above, the present invention has the advantage that it is possible to simultaneously support, that is, mix the time division duplexing scheme and the frequency division duplexing scheme in a communication system using one transceiver. In addition, the signal transmission and reception apparatus has an advantage that it is possible to use a high output amplifier that supports both the time division duplexing scheme and the frequency division duplexing scheme.

Claims (33)

A signal transmitting and receiving device in a communication system, An amplifier for amplifying the transmission signal power, A bias controller for generating a bias for controlling an operation of the amplifier and applying the generated bias; Receives a duplexing scheme selection signal corresponding to a frequency division duplexing scheme or a time division duplexing scheme and a transmission / reception operation signal corresponding to a signal transmission / reception operation of the time division duplexing scheme, and receives the duplexing scheme selection signal and the transmission / reception operation. A power amplification control unit for controlling an operation of the bias control unit using a signal; The amplifier includes a drive amplifier and a main amplifier for amplifying the transmission signal power under the control of the bias control unit. delete The method of claim 1, And the power amplifying control unit controls the bias control unit to apply the bias to the amplifier when the current signal transmission / reception method is a frequency division duplexing method through the duplexing method selection signal. The method of claim 1, The power amplification controller determines that the current signal transmission / reception scheme is a time division duplexing scheme through the duplexing scheme selection signal, and receives the transmission / reception operation signal and confirms that the signal transmission operation is performed, the bias is applied to the amplifier. Signal transmitting and receiving device characterized in that for controlling the bias control unit. The method of claim 1, When the power amplification control unit confirms that the current signal transmission / reception scheme is a time division duplexing scheme through the duplexing scheme selection signal and receives the transmission / reception operation signal and confirms that the signal reception operation is performed, the power amplification control unit does not apply the bias to the amplifier. Signal transmitting and receiving device, characterized in that for controlling the bias control unit. The method of claim 1, And a system controller for providing the duplexing method selection signal and the transmission / reception operation signal to the power amplification controller. The method of claim 1, The transmit / receive operation signal uses at least one of a transistor transistor logic (TTL) signal, a low voltage transistor transistor logic (LVTTL) signal, and a low voltage differential signaling (LVDS) signal. Signal transceiver. The method of claim 1, And a switch for switching the received signal received through the antenna to a low noise amplifier of the signal receiver through an on / off operation. 9. The method of claim 8, And the switch is turned on when the signal transceiver is operated in a frequency division duplexing scheme to switch the received signal to the low noise amplifier. 9. The method of claim 8, And the switch is turned off when the signal transmission / reception device performs a time division duplexing transmission operation so as not to switch the received signal to the low noise amplifier. 9. The method of claim 8, And the switch switches on the received signal to the low noise amplifier when the signal transmission and reception device performs a time division duplexing reception operation. The method of claim 6, The system controller generates a switch control signal and controls the switch using the switch control signal. The method of claim 1, The bias control unit receives a direct current from a power supply, and the signal transmission and reception device, characterized in that to generate a bias current through the control of the power amplification control unit to apply the bias current to the amplifier. The method of claim 1, And the bias is one of a bias voltage and a bias current. A signal transmitting and receiving device in a communication system, A system controller for selecting a duplexing method used for signal transmission and reception among a time division duplexing method and a frequency division duplexing method, and generating a duplexing method selection signal corresponding to the selected duplexing method; A power amplifier configured to receive the duplexing scheme selection signal, generate a bias to control at least one amplifier according to the received duplexing scheme selection signal, and control the at least one amplifier using the generated bias Include, And the power amplifier comprises the at least one amplifier, wherein the at least one amplifier comprises a driving amplifier and a main amplifier for amplifying a transmission signal power by the bias. delete 16. The method of claim 15, And confirming that the current signal transmission / reception scheme is a frequency division duplexing scheme through the duplexing scheme selection signal, and applying the bias to the amplifier to amplify the transmission signal power. 16. The method of claim 15, And the system controller generates a transmission / reception operation signal according to the signal transmission / reception operation of the time division duplexing method. The method of claim 18, The power amplifier determines that the duplex method used to transmit and receive the current signal through the duplexing method selection signal is a time division duplexing method, and when the signal transmission operation is performed through the transmission / reception operation signal, the amplifier receives the transmission signal power. And applying the bias to amplify. The method of claim 18, The power amplifier determines that the duplex method used to transmit and receive the current signal through the duplexing method selection signal is a time division duplexing method, and when the signal reception operation is performed through the transmission / reception operation signal, the amplifier receives the transmission signal power. And the bias is not applied to prevent amplification. The method of claim 18, The transmit / receive operation signal uses at least one of a transistor transistor logic (TTL) signal, a low voltage transistor transistor logic (LVTTL) signal, and a low voltage differential signaling (LVDS) signal. Signal transceiver. 16. The method of claim 15, The signal transmitting and receiving device further comprises a switch for switching the received signal received through the antenna to the low noise amplifier of the signal receiving unit through an ON / OFF operation. 23. The method of claim 22, The system controller generates a switch control signal for turning on the switch when the signal transmission / reception apparatus operates in the frequency division duplexing scheme, and turns off the switch in the case of performing the time duplexing signal transmission. And generating a switch control signal to control the switch by generating a switch control signal to turn on the switch when the time duplexing signal receiving operation is performed. 16. The method of claim 15, And the bias is one of a bias voltage and a bias current. A method for transmitting and receiving signals in a communication system, Determining a duplexing method used for transmitting and receiving a signal among a time division duplexing method and a frequency division duplexing method; Generating a bias for controlling an operation of an amplifier for amplifying a transmission signal power corresponding to the determined duplexing scheme; Controlling the amplifier through the generated bias; Signal transmitting and receiving method comprising the step of correcting the gain of the amplifier. 26. The method of claim 25, And if the duplexing scheme used for transmitting and receiving the signal is a frequency division duplexing scheme, applying the bias to the amplifier to amplify the transmission signal power. 26. The method of claim 25, If the duplexing method used for transmitting and receiving the signal is a frequency division duplexing method, the signal transmitting and receiving method further comprising the step of switching the signal received through the antenna to be input to the low noise amplifier of the receiver. 26. The method of claim 25, And if the duplexing method used to transmit and receive the signal is a time division duplexing method and corresponds to a signal transmission operation, applying the bias to the amplifier to amplify the transmission signal power. 26. The method of claim 25, If the duplexing method used for the transmission and reception of the signal is a time division duplexing method and a signal transmission operation, switching the signal received through the antenna so as not to be input to the low noise amplifier of the receiver. 26. The method of claim 25, And if the duplexing method used for transmitting and receiving the signal is a time division duplexing method and corresponds to a signal reception operation, not applying the bias so that the amplifier does not amplify the transmission signal power. 26. The method of claim 25, If the duplexing method used for transmitting and receiving the signal is a time division duplexing method and the signal reception, the signal transmission and reception method further comprising the step of switching the signal received through the antenna to be input to the low noise amplifier of the receiver. 26. The method of claim 25, And the bias is one of a bias voltage and a bias current. delete

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