KR20070052020A - Automatic gain controller in receiver for communication system with discontinuous transmission and method thereof - Google Patents

Abstract

The present invention relates to an automatic gain control apparatus and method for a receiver of a discontinuous transmission system. The automatic gain control apparatus according to the present invention further includes an information transmission section determination unit detecting an information transmission section in a general automatic gain control apparatus, and by this configuration, the gain can be properly adjusted for the information transmission section in the discontinuous transmission structure. have.

Automatic gain controller, energy averager, energy comparator

Description

Automatic gain controller in receiver for communication system with discontinuous transmission and method

1 is a view showing the configuration of a general automatic gain control device.

2 is a diagram showing the configuration of a general receiver to which the present invention is applied.

3 is a diagram illustrating a configuration of an automatic gain control apparatus for a discontinuous transmission structure according to an embodiment of the present invention.

4 is a diagram illustrating a method for determining an information interval in a discontinuous transmission structure according to an embodiment of the present invention.

The present invention relates to an automatic gain control apparatus and method, and more particularly, to an automatic gain control apparatus and method for a receiver of a discontinuous transmission system.

In general, a receiver of a wireless communication system includes a variable gain amplifier that adjusts a gain of a received signal. Such automatic change of the signal gain of the variable gain amplifier is called automatic gain control. do. An automatic gain control device having such automatic gain control functions to supply a signal of a predefined level to the signal detector by keeping the signal within the operating range of the device.

1 is a view showing the configuration of a general automatic gain control device.

As shown in FIG. 1, a typical automatic gain control device includes a gain control amplifier (hereinafter referred to as "GCA") 101, a detector 102, a filter 103, and an adder 104. .

The GCA 101 amplifies the input signal z (t) by the set gain. The detector 102 detects the energy of the signal y (t) output from the GCA 101. The adder 104 outputs the signal V _D (t) output from the detector 102 to the filter 103 by adding the reference signal -V _R. The filter 103 inputs and filters the output signal of the adder 104 and outputs the filtered signal V _C (t) to the GCA 101. Signal V _C (t) is GCA (101) as a control signal for adjusting the gain, based on the energy signal V _D (t) of the output signal y (t) of GCA (101) by a control signal of -V _R Is controlled to match.

In order to control the control signal V _C (t) in this way, the gain constant of the filter 103 is set experimentally or in accordance with the requirements of the communication system. In this case, if the set time constant is too small, the response is slow and is too large. The problem that the level of the gain-adjusted signal oscillates can result in performance degradation of the receiving system.

Meanwhile, in the case of a discontinuous transmission system in which a signal is divided into an information transmission section and an information non-transmission section, a reception signal level between the non-transmission section (noise section) and the transmission section may change rapidly. Therefore, if the conventional automatic gain control device described above is applied to the discontinuous transmission system as it is without considering the information non-transmission period, the gain adjustment for the signal of the transmission period of the automatic gain control device may not be properly performed.

It is therefore an object of the present invention to provide an automatic gain control device that operates to provide a received signal of a certain characteristic to a demodulator by appropriately adjusting the information transmission interval signal in a discontinuous transmission system.

Another object of the present invention is to provide a method of detecting a transmission interval in a discontinuous transmission system and controlling a gain of an automatic gain control apparatus for a transmission interval and a non-transmission interval.

Automatic gain control device according to a feature of the present invention for achieving the technical problem is an automatic gain control device of a receiver including a variable gain control amplifier in a discontinuous transmission system for transmitting a signal divided into an information transmission section and an information non-transmission section as,

A detector for detecting an energy value of a received signal, a transmission section determination unit for determining whether the received signal is an information transmission section signal or an information non-transmission section signal based on the energy value detected by the detector, and the transmission section determination And a filter for generating an adjustment signal for controlling the gain of the signal in the information transmission section and providing the control signal to the variable gain control amplifier according to a negative determination result.

In addition, the automatic gain control method according to a feature of the present invention,

Detecting an energy value of a received signal; determining whether the received signal is an information transmission section signal or an information non-transmission section signal based on the detected energy value; and according to the determination result, the information transmission section Generating a control signal for controlling the gain of the signal and providing the control signal to the variable gain control amplifier.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

When any part of the specification is to "include" any component, this means that it may further include other components, except to exclude other components unless specifically stated otherwise.

2 is a block diagram showing the structure of a general receiver to which the present invention is applied.

As shown in FIG. 2, a general receiver to which the present invention is applied includes a receiving antenna 201, a low noise amplifier (hereinafter referred to as an "LNA") 202, a band pass filter (hereinafter referred to as "LNA"). BPF "(203), frequency converter 204, BPF 205, intermediate frequency (hereinafter referred to as" IF ") amplifier 206, frequency converter 207, low pass filter (Low Pass) Filter (hereinafter referred to as "LPF") 208 and demodulator 209.

The LNA 202 amplifies only a signal without amplifying noise among radio frequency (hereinafter, referred to as "RF") signals received through the reception antenna 201. The BPF 203 removes noise from the signal amplified in the LNA 202. The frequency converter 204 converts the RF signal into an IF frequency signal. The BPF 205 converts the signal converted to the IF frequency to baseband. The LPF 208 passes only the low frequency signal of the input signal. The demodulator 209 demodulates the signal according to the characteristics of the communication system to which the receiver is applied, and includes an automatic gain control apparatus according to an embodiment of the present invention to be described later.

3 shows a configuration of a demodulator 209 including an automatic gain control device according to an embodiment of the present invention. For convenience of description, only the automatic gain control device and the related components are shown in the demodulator.

As shown in FIG. 3, the automatic gain control apparatus according to the embodiment of the present invention includes an energy detector 301, an adder 302, a filter 303, and a transmission section determination unit 304.

The energy detector 301 detects energy of a signal input to the demodulator 209 through the IF amplifier 206, the frequency converter 207, and the LPF 208. The adder 302 outputs the signal V _D (t) output from the energy detector 301 to the filter 303 by adding the reference signal -V _R. The transmission section determination unit 304 receives the output signal V _D (t) of the energy detector 301, determines whether the signal is a transmission section signal or a non-transmission section signal, and outputs the result to the filter 303. The filter 303 receives the output signals of the adder 302 and the transmission section determination unit 304 and generates an adjustment signal V _C (t) for only the transmission section signal and outputs it to the IF amplifier 206.

The transmission section determination unit 304 includes an energy averager 304b and a comparator 304a. The energy averager 304b includes N shift buffers for storing the output signal V _D (t) of the energy detector 301, and the energy detector 301 for the received signal before the operation time of the energy detector 301. The output signals V _D (t) are stored in the shift buffer, and then the average value V _{D_AVE} (t) of the transmission interval signal is calculated among the values stored in the shift buffer according to the output signal of the comparator 304a and output to the comparator 304a. do. The comparator 304a compares the output signal V _D (t) of the energy detector 301 with the average value V _{D_AVE} (t) transmitted from the energy _averager 304b to determine whether the currently received signal is a transmission section signal or a non-transmission section. It is determined whether the signal is a (noise section) signal, and the determination result is transmitted to the filter 303 and the energy averager 304b. As described above, the transmission interval determination information transmitted from the comparator 304a to the energy averager 304b is used when the energy averager 304b obtains an energy average value of the transmission interval signal among the values stored in the shift buffer. The transmission interval determination information transmitted to the filter 303 is used as information for determining whether to update the filter 303.

FIG. 4 is a flowchart showing the operation procedure of the comparator 304a shown in FIG.

As shown in FIG. 4, the comparator 304a first receives the signal V _{D_AVE} (t) output from the energy _averager 304b and the signal V _D (t) output from the energy detector 301 (S401). In operation _S402 , a value obtained by multiplying a signal V _{D_AVE} (t) by a predetermined factor and a magnitude of the signal V _D (t) are compared (S402). As a result of the comparison, if the signal V _D (t) is greater than the signal V _{D_AVE} (t) multiplied by a factor, the comparator 304a determines that the received signal V _D (t) is a transmission interval signal and stores the information about the energy averager. The data is transmitted to the 304b and the filter 303 (S403). Then, the energy _averager 304b calculates V _{D_AVE} (t) by including the current received signal V _D (t), and the filter 303 calculates the signal V _D (t) and the reference signal (-V _R ). The control signal V _C (t) is updated according to the signal output from the adder 302.

On the other hand, if the signal V _D (t) is less than or equal to the signal V _{D_AVE} (t) multiplied by a factor, the comparator 304a determines that the received signal V _D (t) is a non-transmission section (noise section) signal. In operation S404, the determination result is transmitted to the energy averager 304b and the filter 303. The energy _averager 304b then does not include the current received signal V _D (t) in the calculation of V _{D_AVE} (t), and the filter 303 does not update the control signal V _C (t) and remains at the previous state value. do.

In FIG. 4, the factor value is set by using a structure of a transmission system, a size of a noise signal in a non-transmission section, and a change in a signal size in a transmission section.

As such, since the filter 303 updates the control signal V _C (t) only in the transmission period, the gain of the IF amplifier 206 may be automatically controlled according to the signal of the transmission period.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concepts of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

As described above, the present invention detects the energy of the received signal and obtains an average value to determine whether the received signal is a transmission section signal or a non-transmission section (noise section) signal, and adjust the automatic gain control operation according to the determination result. do. By defining the automatic gain control operation in the transmission section and the non-transmission section (noise section) as described above, the design margin is determined in determining the overall time constant of the automatic gain controller according to the signal level difference between the transmission section and the non-transmission section. Can bring

Claims (8)

An automatic gain control apparatus for a receiver including a variable gain control amplifier in a discontinuous transmission system for transmitting a signal divided into an information transmission section and an information non-transmission section, A detector for detecting an energy value of a received signal; A transmission section determination unit determining whether the received signal is an information transmission section signal or an information non-transmission section signal based on the energy value detected by the detector; And a filter configured to generate an adjustment signal for controlling the gain of the signal in the information transmission section and provide the control signal to the variable gain control amplifier according to a determination result of the transmission section determining unit. The method of claim 1, The transmission section determination unit, An energy averager for calculating an average value of energy values of the information transmission interval among the energy values detected by the detector; And a comparator comparing the energy value detected by the detector with the average value calculated by the energy averager to determine whether a signal currently received is a signal of the information transmission section or a signal of the non-transmission section. The method of claim 2, The comparator, If the energy value output from the energy detector is greater than a value multiplied by a preset factor by the average value output from the energy averager, it is determined that the currently received signal is a signal of the information transmission interval and the control signal for updating the filter is determined. Output, If the energy value output from the energy detector is less than or equal to the value obtained by multiplying the preset factor by the average value output from the energy averager, the current received signal is determined to be a signal of the information non-transmission interval, and the filter is applied. Automatic gain control device that outputs an adjustment signal to maintain the state. The method of claim 3, The energy averager, And calculating the energy average value by including the currently received signal when it is determined that the currently received signal is a signal of the information transmission interval based on the information transmission interval determination signal output from the comparator. In the automatic gain control method of a receiver including a variable gain control amplifier in a discontinuous transmission system for transmitting a signal divided into an information transmission section and an information non-transmission section, Detecting an energy value of a received signal; Determining whether the received signal is an information transmission section signal or an information non-transmission section signal based on the detected energy value; And generating a control signal for controlling the gain of the signal in the information transmission section and providing the control signal to the variable gain control amplifier according to the determination result. The method of claim 5, The process of determining the information transmission section signal, Calculating an average value of energy values of the information transmission interval among the detected energy values; And comparing the detected energy value with the calculated average value to determine whether a currently received signal is a signal of the information transmission section or a signal of the non-transmission section. The method of claim 6, The process of determining the information transmission section signal, If the detected energy value is greater than a value obtained by multiplying the calculated average value by a preset factor, it is determined that the currently received signal is a signal of the information transmission interval, and wherein the detected energy value is the calculated average value by the preset factor. If the multiplication value is less than or equal to the automatic gain control method for determining that the currently received signal is a signal of the information transmission interval and outputs a signal according to the determination result. The method of claim 6, The process of calculating the average energy value, And calculating the energy average value by including the currently received signal when it is determined that the currently received signal is a signal of the information transmission interval based on the signal according to the information transmission section determination result.

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