KR100937851B1 - A radiotelegraph having a function of assigining multicarrier frequency and the method thereof - Google Patents

Abstract

In the present invention, a multicarrier frequency can be prevented from spreading out of an unused frequency component of a multicarrier caused by a nonlinear characteristic of a transmitter power amplification in a radio for a high speed data communication using a multicarrier. A radio communication apparatus and a method for a high speed data communication having a multi-carrier allocation function for reassignment,

A high speed data communication radio having a multi-carrier allocation function includes: an RF unit for performing transmission and reception of RF signals by performing down and up-conversion on multicarriers for each channel for high speed data communication; An unwanted wave measuring unit measuring an unnecessary wave band for multi-carriers for each channel for high-speed data communication amplified and transmitted by the RF unit; Controls the transmission and reception of the RF unit, and after receiving the unwanted band value generated in the multicarriers for each channel measured by the unwanted wave measuring unit, the unnecessary wave of each of the multicarriers is a multicarrier frequency band of an adjacent channel. And a control unit for reallocating the frequencies of the multicarriers for each channel in the used frequency band so as to have a gap that does not overlap with each other.

High speed data communication, walkie-talkie, multicarrier, unwanted wave, unwanted wave spread

Description

Radio for high speed data communication with multicarrier allocation function and method {A RADIOTELEGRAPH HAVING A FUNCTION OF ASSIGINING MULTICARRIER FREQUENCY AND THE METHOD THEREOF}

In the present invention, a multicarrier frequency can be prevented from spreading out of an unused frequency component of a multicarrier caused by a nonlinear characteristic of a transmitter power amplification in a radio for a high speed data communication using a multicarrier. The present invention relates to a radio for a high speed data communication having a multi-carrier allocation function for reassignment and a method thereof.

In general, a radio for high speed data communication that performs voice and high speed data communication uses a multi-carrier. In this case, the multicarrier generates an unwanted wave component due to the nonlinear characteristics of the transmitter power amplifier.

1 and 2 are diagrams illustrating the spreading of undesired waves in a radio for a high speed data communication using a multicarrier of the prior art as described above, and FIG. 1 shows that undesired waves of a multicarrier are spread out to one side outside a frequency band used. FIG. 2 is a diagram showing that unwanted waves of a multicarrier having a wide carrier interval are spread to both sides.

That is, as shown in FIGS. 1 and 2, when the multicarriers are amplified, an undesired wave A is generated and spread to the multicarrier band M of the adjacent frequency band or the adjacent channel. Since the unwanted wave generated in the high speed data communication radio using the multi-carrier of the prior art is spread to the adjacent multi-carrier channel region and causes interference of the adjacent channel, it is necessary to prevent it.

Therefore, in the prior art, the power amplifier linearization and back-off method is applied to prevent the interference of the adjacent channel due to the unnecessary wave of the multi-carrier as described above.

However, the method of using the power amplifier linearization and the backoff as a method of suppressing the unwanted components occurring in the multicarriers of the prior art as described above increases the size of the circuit, thereby increasing the current consumption. There are a number of problems that follow.

Accordingly, the present invention is to solve the above-mentioned problems of the prior art, to prevent the unwanted components caused by the non-linear characteristics of the transmitter power amplifier in the radio using a multi-carrier (Multi Carrier) to interfere with the adjacent channel. It is an object of the present invention to provide a radio and a method for a high-speed data communication having a multi-carrier allocation function for reallocating the interval of the frequency of each communication channel of the radio so that it can be.

Radio for high speed data communication having a multi-carrier allocation function of the present invention for achieving the above object,

An RF unit for performing transmission and reception of RF signals by performing down and up-conversion on multicarriers per channel for high-speed data communication;

An unwanted wave measuring unit measuring an unnecessary wave band for multi-carriers for each channel for high-speed data communication amplified and transmitted by the RF unit;

Controls the transmission and reception of the RF unit, and after receiving the unwanted band value generated in the multicarriers for each channel measured by the unwanted wave measuring unit, the unnecessary wave of each of the multicarriers is a multicarrier frequency band of an adjacent channel. And a control unit for reallocating the frequencies of the multicarriers for each channel in a used frequency band so as to have a channel interval not overlapping with the channel.

The controller may set the frequencies of the multicarriers for each channel such that the channels for the high speed data communication with which the channel intervals are reassigned are arranged in the center of the use frequency band.

The controller may adjust the frequency of the single carrier so that the voice communication channel having a single carrier for voice communication is sequentially arranged at both sides of the channel of the multicarriers for the high-speed data communication, which are arranged at the center within the frequency band used. It is characterized by assigning.

Multi-carrier allocation method of radio for high speed data communication,

An unnecessary band measurement process for measuring an unnecessary band of multicarriers for each channel for high speed data communication;

A channel interval setting step of setting a channel interval so that the unwanted wave band does not interfere with a multicarrier frequency band of an adjacent channel;

And a multicarrier frequency setting step of setting the frequencies of the multicarriers for each channel so that the channels for the high speed data communication having the channel intervals are positioned at the center of the use frequency band.

In the above-described multicarrier frequency setting process of the present invention, a single carrier frequency of a voice channel is set such that a single carrier of each voice channel for voice communication is disposed at both sides of a high-speed data communication channel disposed in the center of a frequency band used. Characterized in that it further comprises a voice channel arrangement process for placing the voice channel.

According to the present invention having the above-described configuration, in the radio using multicarrier for high-speed data communication, unnecessary waves generated in the multicarrier amplified without the addition of a linearization circuit or an output power back off circuit of a power amplifier are adjacent to each other. To prevent interference with the channel.

The present invention described above can prevent radio waves from interfering with adjacent channels in radios using multicarriers for high-speed data communication without the addition of linearization circuits or output power back-off circuits. It can be miniaturized to reduce the cost, and it provides the effect of extending the operating time of the radio by reducing the current used by miniaturization.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings.

3 is a block diagram of a radio for a high speed data communication (hereinafter referred to as a "radio") having a multi-carrier allocation function according to an embodiment of the present invention.

As shown in FIG. 3, the transceiver 100 according to an exemplary embodiment of the present invention includes an RF unit (RF unit) 110 that performs RF signal transmission and reception, and a non-linear power amplifier of a transmitting end of the RF unit 110. The wave measurement unit 120 for measuring the unnecessary wave band generated in the multicarrier for each channel from the output transmission signal, the control unit 130 for performing communication control and channel assignment control, and a key for receiving a user input command And an input unit 140, a microphone 150 for voice input, a speaker 160 for outputting an audio signal, and a display unit 170 for displaying a driving state and transmission / reception data of the radio 100. Although not shown is configured to include a storage unit for storing transmission and reception data and driving data and a battery for power supply.

In the above-described configuration, the RF unit 110 converts the baseband signal into an intermediate band and a high frequency band for transmission of the RF signal, and then amplifies and transmits the upconverter unit, and converts the received high frequency signal into the intermediate band and the baseband. After that, a down converter unit for outputting to the control unit is provided to transmit and receive an RF signal according to a control command of the control unit 130. Since the RF unit 110 includes a power amplifier for amplifying transmission power and a low noise removing filter for removing noise in the reception power, it is obvious in the related art, and thus a detailed description thereof will be omitted.

The unnecessary wave measuring unit 120 extracts an output signal of the high power amplifier for amplifying the transmission power of the RF unit 110 and measures the unnecessary wave band generated in the multicarrier for high speed data communication during the amplification process. The measured unwanted band value is output to the controller.

The control unit 130 controls the transmission and reception of the RF unit 110, and after receiving the unnecessary wave band value generated in the multi-carrier for each channel measured by the wave measurement unit of each of the multicarriers The frequency of the multicarriers for each channel is reassigned in the used frequency band so that the unwanted waves have an interval not overlapping the multicarrier frequency band of the adjacent channel. In this process, the control unit 130 sets each channel frequency such that each channel is located at the center within the frequency band used after allocating frequency intervals for the multicarriers of the channels through the high speed data communication. And the voice communication channel having a single carrier sets the frequency so as to be located at both sides of all the high-speed data channels arranged in the center portion of the frequency band used. At this time, the multicarrier transmitted and received by the controller 130 becomes an OFDM signal.

In the description of the radio 100 of FIG. 3 and the above-described FIG. 3, the unwanted wave measuring unit 120 is illustrated and described as being separately configured from the control unit 130, but this is only for clarity of the present invention and the present invention. However, the present invention is not limited thereto, and thus the unwanted wave measuring unit 120 may be integrated in the control unit 130 or variously implemented by other methods.

4 is a flowchart illustrating a process of a multi-carrier allocation method of a radio communication apparatus for high speed data according to the present invention, FIG. 5 is a diagram illustrating a setting state of a channel interval having a multicarrier, and FIG. Referring to FIG. 3 to FIG. 6, a process of a multi-carrier allocation method of a radio for high data communication according to the present invention will be described with reference to FIGS. 3 to 6.

First, the radio wave measurement unit 120 of the radio unit measures the unwanted wave band generated in each multicarrier from the transmission high frequency signal output from the high power amplifier of the transmitting unit of the RF unit 110 (fluid wave measurement process). (S1).

In the above-described process, the measured value of the unnecessary wave band generated in the multicarrier for each channel measured by the unwanted wave measuring unit 120 is input to the control unit 130, and the control unit 130 is provided from the unnecessary wave measuring unit 120. The input wave band measurement is analyzed to set channel intervals such that the unwanted wave generated in each multicarrier for each channel does not interfere with the multicarrier frequency of an adjacent band. That is, as shown in FIG. 5, the channel spacing is set so that the unwanted wave band A generated in each multicarrier band M does not interfere with the multicarrier band M of adjacent channels (channel spacing). Setting process) (S2).

Thereafter, the controller 130 reallocates the frequency band of the multicarrier for each channel such that the entire high speed data channel is positioned at the center of the frequency band while the channels for the high speed data communication have the channel interval set in the above process. FIG. 6 shows that the multicarrier frequencies for each channel are reassigned so that the channels for high-speed data communication are located in the center of the frequency band used. It indicates that the frequencies of the multicarriers have been allocated so as to have an interval to avoid (multicarrier frequency allocation process) (S3).

Next, the controller 130 allocates a single carrier frequency of the voice communication channel such that the voice communication channel having a single carrier is arranged at both sides of the channels having the multicarrier for high speed data communication located at the center of the frequency band used. In this process, the single carriers S of the allocated voice channel are disposed at both sides of the channels having the multicarriers for high-speed data communication, as shown in FIG. 6. The interference with the communication channel is prevented (voice channel arrangement process) (S4).

1 is a view showing that the unnecessary wave of the multi-carrier generated in the radio for high-speed data communication using the multi-carrier of the prior art converted out of the frequency band used,

2 is a view showing that the undesired waves of a multicarrier of the prior art having a wide carrier interval are spread to both sides of a frequency band used;

3 is a block diagram of a radio for high speed data communication having a multi-carrier allocation function according to an embodiment of the present invention (hereinafter referred to as "radio"),

4 is a flowchart illustrating a process of a multi-carrier allocation method of a radio for high speed data communication of the present invention;

5 is a diagram illustrating a setting state of intervals of channels having multicarriers;

6 is a diagram illustrating a state in which high-speed data communication channels and a voice communication channel are arranged in a frequency band used.

Description of the main symbols in the drawings

100: radio 110: RF part (RF part)

120: unnecessary wave measuring unit 130: control unit

140: key input unit 150: microphone

160: speaker 170: display unit

Claims (5)

An RF unit for performing transmission and reception of RF signals by performing down and up-conversion on multicarriers per channel for high-speed data communication; An unwanted wave measuring unit measuring an unnecessary wave band for multi-carriers for each channel for high-speed data communication amplified and transmitted by the RF unit; Controls the transmission and reception of the RF unit, and after receiving the unwanted band value generated in the multicarriers for each channel measured by the unwanted wave measuring unit, the unnecessary wave of each of the multicarriers is a multicarrier frequency band of an adjacent channel. And a control unit for reallocating the frequencies of the multicarriers for each channel in a used frequency band so as to have a channel interval not overlapping with each other. 2. The method according to claim 1, wherein the control unit, 2. The radio for high speed data communication having a multi-carrier allocation function, wherein the frequencies of the multicarriers for each channel are set such that channels for high speed data communication with which the channel intervals are reassigned are arranged in a center of a frequency band used. The method according to claim 2, The control unit, The frequency of the single carrier is allocated such that a voice communication channel having a single carrier for a voice call is sequentially arranged at both sides of a channel of the multicarriers for the high-speed data communication arranged in the center within the frequency band used. Radio for high speed data communication with multicarrier allocation function. An unnecessary band measurement process for measuring an unnecessary band of multicarriers for each channel for high speed data communication; A channel interval setting step of setting a channel interval so that the unwanted wave band does not interfere with a multicarrier frequency band of an adjacent channel; A multicarrier frequency setting step of setting the frequencies of the multicarriers for each channel so that the channels for the high speed data communication arranged in the channel intervals are located at the center of a frequency band used. Assignment method. The method of claim 4, wherein the multicarrier frequency setting process comprises: A voice channel arrangement process of arranging a voice channel by setting a single carrier frequency of the voice channel so that a single carrier of each voice channel for voice communication is arranged at both sides of the high-speed data communication channel disposed in the center of the frequency band used. A multi-carrier allocation method of a radio for high speed data communication, further comprising.

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