KR101102666B1 - Transmitter of wibro terminal - Google Patents

Abstract

The present invention relates to a transmission apparatus of a WiBro terminal capable of reducing noise and spurious signals when transmitting data through a transmission channel in a WiBro terminal, and comprising: a power amplifier module for amplifying and outputting power of an input signal; The main amplifier for amplifying and outputting the signal input from the power amplifier module, and the first signal input from the power amplifier module and a second signal inverted the phase of the signal input from the amplifying unit respectively received and the input A noise extractor which extracts and generates a phase inverted noise by adding a first signal and a second signal, and combines a signal input from the main amplifier and noise whose phase is inverted from the noise extractor It includes a coupler to remove and output.

WiBro, Terminal, Transmission, Noise, Spurious

Description

Transmission device of WiBro terminal {TRANSMITTER OF WIBRO TERMINAL}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a WiBro terminal, and more particularly, to an apparatus for transmitting a WiBro terminal, which can reduce noise and spurious signals when transmitting data through a transmission channel.

At present, WiBro, a wireless mobile Internet that provides high-speed internet access, is being serviced in some areas.

As WiBro's portable Internet business is in full swing, leading domestic companies are actively adopting the WiBro system. The WiBro is also called Mobile WiMAX.

WiBro uses TDD (Time Division Duplexer) frequency of 2.3 GHz to 2.4 GHz band, where multiple base stations are multiplexed through one repeater and the same frequency band is divided in time to It refers to a time division multiple access method that communicates with each other so as not to overlap.

Here, the TDD scheme can operate in a saturation region because when a plurality of base stations are multiplexed using one repeater, even if the number of accessing base stations increases, the TDD method divides the signal with a predetermined period using a time delay. Do.

Since the WiBro system uses the reception channel (Rx) and the transmission channel (Tx) in the same frequency band, a time delay may occur between the data of the reception channel and the data of the transmission channel in the repeater and is applicable to the WiBro repeater. And low noise characteristics.

The present invention is to provide a transmission apparatus of the WiBro terminal that can improve the performance of the transmission channel by reducing the emission of noise and spurious signals included in the transmission signal when transmitting data through the transmission channel in the WiBro terminal.

Technical problems to be achieved by the present invention are not limited to the above-mentioned technical problems, and other technical problems not mentioned above may be clearly understood by those skilled in the art from the following description. There will be.

Transmission apparatus of the present invention for achieving the above object, the power amplification module for amplifying and outputting the power of the input signal; A main amplifier for amplifying and outputting a signal input from the power amplifier module; The first signal input from the power amplification module and the second signal inverted in phase of the signal input from the amplifying unit are respectively input, and the first signal and the second signal are added to extract noise whose phase is inverted. And a noise extracting unit to generate. And a combiner for combining the signal input from the main amplifier and the noise whose phase input from the noise extracting unit is inverted to remove and output the noise.

Specifically, the noise extracting unit comprises: a first coupler for extracting a signal of a predetermined power by coupling a main signal output through the power amplification module; A second coupler for coupling a signal output through the main amplifier to extract a signal of a predetermined power; A phase inversion unit for inverting a phase of a signal input from the second coupler; An adder configured to add a main signal input through the first coupler and a phase inverted signal input through the phase inversion unit to remove the main signal, and then output an inverted noise signal; And a noise amplifier for amplifying the noise input through the adder.

As described above, the present invention has an advantage of improving performance of a transmission channel by removing noise included in a transmission signal and reducing radiation of a spurious signal when transmitting data through a transmission channel in a WiBro terminal.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention. Like elements in the figures are denoted by the same reference numerals wherever possible. In addition, detailed descriptions of well-known functions and configurations that may unnecessarily obscure the subject matter of the present invention will be omitted.

1 is a view showing a transmission and reception apparatus of a WiBro terminal according to the present invention, wherein the transmission and reception apparatus 10 includes a path switching means 11, a high pass filter unit 13, a low pass filter unit 15, and a power amplification module ( 17) and the like.

The path switching means 11 is connected to the antenna side and switched according to an external control signal to switch the signal transmission channel to the reception mode or the transmission mode. For example, the path switching means 11 is switched according to an external control signal to switch the WiBro terminal to a reception mode or a transmission mode.

The high pass filter unit 13 is connected to the transmission terminal Tx of the path switching means 11 to block low frequency signals and pass only high frequency signals among the signals transmitted to the antenna. WiBro uses frequencies in the 2.3 GHz to 2.4 GHz band, for example, so that a signal having a cutoff frequency of 2.0 GHz and a higher frequency can pass.

The low pass filter unit 15 is connected to the high pass filter unit 13 to block the high frequency signal among the signals transmitted to the high pass filter unit 13 and pass only the low frequency signal. WiBro uses frequencies in the 2.3 GHz to 2.4 GHz band, for example, so that only signals having a frequency lower than 2.7 GHz can pass.

When the control signal for the transmission mode is input from the outside, the path switching unit 11 switches the switch to the transmission terminal Tx, and transmits the WiBro transmission signal input through the high pass filter unit 13 to the antenna.

If the path switching means 11 receives a control signal for a reception mode from the outside, the switch is switched to the reception terminal Rx to output the received WiBro received signal through the antenna to the reception channel Rx Path.

The power amplifier module 17 is located in the transmission channel and power amplifies the input WiBro signal to transfer it to the low pass filter unit 15.

Although not shown, the transmission / reception apparatus may further include a low noise amplifier (LNA) or a filter for removing harmonics included in the WiBro signal.

The transmission apparatus of the WiBro module configured as described above is poor in linearity and output power of the power amplification module and also lacks an EVM (Error Vector Magnitude) margin.

2 is a circuit block diagram illustrating a transmission apparatus of a WiBro terminal according to an exemplary embodiment of the present invention. The transmission apparatus 100 includes a power amplifier module 110, a main amplifier 120, a noise extractor 130, and a second apparatus. The delay unit 140, the combiner 150, the low pass filter 160, and the path switching unit 170 may be formed.

The power amplifier module 110 is located in the transmission channel and amplifies and outputs the input WiBro signal.

The main amplifier 120 amplifies and outputs the signal input from the power amplifier module 110. In this case, the signal amplified by the amplifier 120 may include a spurious signal.

The noise extractor 130 receives a first signal input from the power amplifier module 110 and a second signal inverted in phase of the signal input from the main amplifier 120, respectively, and receives the first signal from the input signal. The second signal is added to extract and generate a noise signal having a reversed phase.

The noise extractor 130 includes a first coupler 131, a first delayer 132, a second coupler 133, a phase inverter 134, an adder 135, and a noise amplifier 136. consist of.

The first coupler 131 extracts and outputs a signal of a predetermined power through a coupling to the main signal output through the power amplifier module 110.

The first delay unit 132 delays and outputs the main signal input from the first coupler 131 for a predetermined time.

The second coupler 133 extracts and outputs a signal of a predetermined power through coupling to a signal output through the main amplifier 120.

The phase inverting unit 134 inverts the phase of the signal input from the second coupler 133.

The adder 135 adds a main signal input through the first delayer 132 and a phase inverted signal input through the phase inverting unit 134 to remove the main signal and outputs an inverted noise signal. .

The noise amplifier 136 amplifies and outputs a noise signal input through the adder 135.

The second delay unit 140 delays a signal input from the main amplifier 120 for a predetermined time and outputs the delayed signal.

The combiner 150 combines the signal input from the second delay unit 140 and the noise inverted phase input from the noise amplifier 136 of the noise extractor 130 to remove and output the noise.

The low pass filter 160 cuts a high frequency signal among the signals input from the combiner 150 and passes only a low frequency signal. WiBro uses frequencies in the 2.3 GHz to 2.4 GHz band, for example, so that only signals having a frequency lower than 2.7 GHz can pass.

The path switching means 170 is configured to switch to a transmission mode according to an external control signal to transmit a signal input from the low pass filter 160 through an antenna. The path switching means 170 is switched according to an external control signal to switch the WiBro terminal to a reception mode or a transmission mode. The path switching means 170 may include a field effect transistor (FET) or a plurality of diode circuits. Can be. The plurality of diodes are turned on and off according to an external control signal to select a transmission channel (Tx Path) or a reception channel (Rx Path), and may be configured as a single pole double throw (SPDT) type.

Looking at the operation of the present invention configured as described above is as follows.

First, the signal output through the power amplifier module 110 is transmitted to the main amplifier 120 and the first coupler 131, the first coupler 131 couples the signal output through the power amplifier module 110 Ring to extract a signal with a predetermined power. Here, the power of the signal extracted through the first coupler 131 is smaller than the signal output from the power amplifier module 110, and is input from the power amplifier module 110 to the main amplifier 120 according to the coupling. The power of the main signal can also be somewhat reduced.

The main amplifier 120 amplifies the signal input from the power amplifier module 110, in which noise, such as harmonics, is generated outside the bandwidth of the main signal as well as the main signal.

The signal output through the main amplifier 120 is transmitted to the second coupler 133 and the second delayer 140, and the second coupler 133 couples the signal output through the main amplifier 120. To extract a signal having a predetermined power. Here, the power of the signal extracted through the second coupler 133 is smaller than the signal output from the main amplifier 120.

The signal output through the second coupler 133 is input to the phase inversion unit 134, and the phase inversion unit 134 inverts the phase of the input signal.

Next, the adder 135 receives and adds a main signal input through the first coupler 131 and the first delayer 132 and a phase inverted signal input through the phase inversion unit 134 to add a phase. After removing these different main signals, only a noise signal having a reversed phase is output.

The noise signal output from the adder 135 is amplified by the noise amplifier 136 and transmitted to the combiner 150.

The combiner 150 receives and combines the signals input from the main amplifier 120 and the second delay unit 140 and the phase-inverted noise input from the noise amplifier 136 of the noise extractor 130, respectively. Therefore, only the noise signal having different phases is removed and only the main signal is output.

The signal output through the combiner 150 is input to the low pass filter 160, and the low pass filter 160 blocks the high frequency signal and passes only the low frequency signal. For example, since the WiBro uses frequencies in the 2.3 GHz to 2.4 GHz band, the low pass filter 160 may pass a signal having a cutoff frequency of 2.7 GHz and a lower frequency.

The signal output through the low pass filter 160 is wirelessly transmitted through the transmitting terminal of the path switching means 170 and the antenna.

The signal output through the low pass filter 160 is shown in the waveform diagram of FIG.

As shown in FIG. 3, the output power performance is excellent in the frequency band of 2.5 GHz or less, and the spurious emission characteristics are significantly improved by the maximum power of -30 dB or less in the frequency band of approximately 4.0 GHz or more, thereby reducing noise and spectral mask performance. appear.

The present invention has been described with reference to the preferred embodiments, those skilled in the art to which the present invention belongs to the detailed description of the present invention and other forms of embodiments within the essential technical scope of the present invention Could be implemented. Here, the essential technical scope of the present invention is shown in the claims, and all differences within the equivalent range will be construed as being included in the present invention.

1 is a view showing a transmission and reception apparatus of a WiBro terminal according to the present invention.

2 is a circuit block diagram illustrating an apparatus for transmitting a WiBro terminal according to an exemplary embodiment of the present invention.

3 is a diagram illustrating a signal waveform output by FIG. 2.

* Explanation of symbols for the main parts of the drawings

100: transmitting device (WiBro terminal) 110: power amplifier module (PAM)

120: main amplifier 130: noise extraction unit

131: first coupler 132: first delay

133: second coupler 134: phase inversion

135: adder 136: noise amplifier

140: second delay unit 150: coupler

160: low pass filter 170: path switching means

Claims (7)

A power amplification module for amplifying and outputting the power of the input signal; A main amplifier for amplifying and outputting a signal input from the power amplifier module; Receiving a first signal input from the power amplifier module and a second signal input from the main amplifier, inverting a phase of the second signal, adding a phase-inverted second signal and the input first signal; A noise extraction unit for extracting and generating noise whose phase is inverted; And And a combiner for removing the noise by combining the signal input from the main amplifier and the inverted phase of the phase input from the noise extracting unit, and outputting the noise. The noise extracting unit may include: a first coupler configured to extract a signal of a predetermined power by coupling a main signal output through the power amplifier module; A second coupler for coupling a signal output through the main amplifier to extract a signal of a predetermined power; A phase inversion unit for inverting a phase of a signal input from the second coupler; An adder configured to add a main signal input through the first coupler and a phase inverted signal input through the phase inversion unit to remove the main signal, and then output a phase inverted noise signal; And a noise amplifier configured to amplify the noise inputted through the adder. The method of claim 1, Among the signals input from the combiner is a transmission apparatus of the WiBro terminal including a low pass filter to block the high frequency signal and pass only the low frequency signal. The method of claim 2, And a path switching unit configured to switch to a transmission mode according to an external control signal to transmit a signal input from the low pass filter unit through an antenna. delete The method of claim 1, And a first delayer disposed between the first coupler and the adder to delay an input signal for a predetermined time. The method of claim 1, And a second delayer installed between the main amplifier and the combiner to delay an input signal for a predetermined time. The apparatus of claim 2, wherein the cutoff frequency of the low pass filter unit is 2.7 GHz.

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