JP2003179450A - Agc controller - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an AGC controller which performs AGC control at each mobile terminal with a short converging time and a few errors. <P>SOLUTION: The controller comprises a variable gain amplifier for amplifying a signal, and an AGC control unit 117 for outputting a signal for adjusting the gain of the amplifier, based on the signal level. The AGC control unit 117 comprises a level-measuring unit 201 for measuring a receiving level A, a memory 203 for storing a target-receiving level B, a subtractor 205 for obtaining a subtraction value C (=B-A), an arithmetic unit 207 for obtaining a gain set value D<SB>n+1</SB>(=D<SB>n</SB>+k)×C<SB>n</SB>) shown by a signal for adjusting the gain of the amplifier, a memory 209 for storing a gain set value D (converged value) last obtained in one frame at each mobile terminal, and a converter 211 for generating a signal from adjusting the gain of the amplifier from the gain set value D in matching the characteristics of the amplifier. A signal outputted from the AGC control unit 117 is D/A converted and fed to the amplifier. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an AGC control device for performing AGC control for each mobile terminal or base station.

[0002]

2. Description of the Related Art FIG. 2 shows a basic configuration of a radio device which obtains a baseband signal by orthogonally demodulating a quadrature-modulated received signal. When the radio is used as a mobile terminal or a base station, the distance between the movable mobile terminal 150 and the base station 10 and the environment (walls, obstacles, reflectors) around the terminal are located at the position of the mobile terminal 150. Therefore, the radios of the base station 10 and the mobile terminal 150 adjust the gain of the amplifier so that the received signal level approaches the specified value before performing the quadrature demodulation. That is, automatic gain control (AGC: Automa)
tic Gain Control). Further, since the gain of the amplifier is adjusted by the signal from the outside, the base station 1
As shown in FIG. 2, the wireless device of 0 and the mobile terminal 150 includes an AGC control unit 17 that outputs a signal to be supplied to the amplifier 109 based on the reception level. Note that, hereinafter, a series of processes such as adjusting the gain of the amplifier 109 based on the reception level is referred to as “AGC control”.

FIG. 7 shows a conventional base station 10 and mobile terminal 1.
The internal structure of the AGC control part 17 with which 50 radio | wireless machine 10 is provided is shown. As shown in the figure, the AGC control unit 17 includes a reception level measurement unit 201, a target level storage unit 203, a subtraction unit 205, a calculation unit 207, and a conversion unit 211. The reception level measuring unit 201 measures the reception level from the I and Q signals obtained by quadrature demodulation. The reception level A is obtained by "I ² + Q ² ". Further, the target level storage unit 203 stores the target level B of the reception level. In addition, the subtraction unit 20
5 subtracts the reception level A obtained by the reception level measuring unit 201 from the target level B stored in the target level storage unit 203 to obtain the subtraction value C (= B−A).

The computing unit 207 also computes a gain setting value indicated by a signal for adjusting the gain of the amplifier 109 (hereinafter referred to as "gain adjustment signal"). More specifically, the (n + 1) th gain setting value D
_{n + 1} is the nth gain setting value D _n and the update coefficient k (0 <
From k <1) and the n-th subtraction value C _n obtained from the subtraction unit 205, the calculation formula of D _{n + 1} = D _n + k × C _n is obtained. Further, the conversion unit 211 uses the gain setting value D obtained by the calculation unit 207 as a D / A unit 119 at the subsequent stage shown in FIG.
In other words, the gain adjustment signal is generated from the gain setting value D. The signal output from the AGC control unit 17 is supplied to the amplifier 109 after being converted from a digital signal to an analog signal by the D / A unit 119.

As described above, the mobile terminal has different radio wave propagation environments depending on the distance from the base station and the surrounding environment (walls, obstacles, reflectors, etc.). Therefore, the reception level of the base station differs for each terminal, and the base station needs to adjust the gain of the amplifier 109 for each terminal. Therefore, in the conventional base station, when the communication system equipped with the base station adopts the time division multiplexing method, the reception level should be adjusted for each frame so that it can communicate with a plurality of mobile terminals in the area. This makes it possible to support a plurality of mobile terminals having different reception levels.

[0006]

The conventional base station 10 described above is used.
In the wireless device of the mobile terminal 150, the AGC controller 17
Although a series of processing from reception level measurement to signal output by the wireless communication device is performed for a predetermined time, since the wireless device communicates with each mobile terminal having different reception level,
The gain setting value D obtained in 07 is initialized for each frame and each terminal. That is, when determining the gain setting value D _{n + 1} at the operation unit 205, the gain setting value D _n of each mobile terminal obtained by the previous frame is not available, AGC control unit 17, the received signal amplitude level Is adjusted to an optimum value from the state of "0".

Therefore, in the conventional radio device, the time (convergence time) required for adjusting the gain of the amplifier 109 to optimize the reception level becomes long.
That is, there is a problem that the pull-in of AGC (automatic gain control) is slow. On the other hand, if the time allotted for gain adjustment is constant, the dynamic range that can be adjusted to the ideal reception level becomes narrow within the fixed time, and if the reception level is outside the dynamic range, AGC control is performed. However, there is a problem in that the error between the received level and the ideal reception level becomes large even when performing.

Each of these problems has a trade-off relationship. That is, if the error is made small, the convergence time becomes long, and if the convergence time is made short, the error becomes large. Therefore, there has been a demand for a wireless device including an AGC control device capable of performing AGC control with a short convergence time and a small error for each mobile terminal.

The present invention has been made in view of the above conventional problems, and an object of the present invention is to provide an AGC control device which performs AGC control for each mobile terminal and has a short convergence time and a small error. .

[0010]

In order to solve the above-mentioned problems, an AGC control device according to the present invention uses an AG for each mobile terminal.
An AGC control device for C control, which supplies a variable gain signal amplifying means for amplifying a received signal from a mobile terminal and a gain adjusting signal for adjusting a gain of the signal amplifying means to the signal amplifying means. AGC control means, wherein the AGC control means obtains a gain set value indicated by the gain adjustment signal by calculation, and a gain set value calculated by the gain set value calculation means within a predetermined time. Gain setting value storage means for storing the convergence value at each mobile terminal, wherein the gain setting value calculation means stores the gain setting value of the corresponding mobile terminal stored in the gain setting value storage means. This is used to calculate a new gain setting value.

Therefore, while performing AGC control for each mobile terminal, the time (convergence time) required for adjusting the gain of the signal amplifying means so that the reception level becomes optimum can be shortened. Further, since the convergence time can be shortened, the error can be reduced by keeping the time for performing the AGC control constant. Furthermore, if the convergence time is constant, a wider dynamic range than before can be realized.

Further, in the AGC control device according to the present invention,
The gain setting value calculating means is a signal level of the reception signal amplified by the signal amplifying means, a target level of the signal level of the reception signal, and a corresponding mobile terminal stored in the gain setting value storage means. A new gain setting value is calculated based on the gain setting value and.

Further, in the AGC control apparatus according to the present invention, the mobile terminal is provided with an identifier for identifying the terminal, and the signal transmitted from the mobile terminal includes the identifier. Therefore, the AGC control device can determine from which mobile terminal the received signal is transmitted.

Further, a base station according to the present invention is defined by claim 1
The AGC control device according to claim 3 is provided. Since the AGC control device according to the present invention is provided,
The base station can obtain good reception characteristics.

Further, the AGC control device according to the present invention is an AGC control device for performing AGC control for each base station, and a gain changeable signal amplification means for amplifying a received signal from the base station, and the signal amplification means. And AGC control means for supplying a gain adjustment signal for adjusting the gain to the signal amplification means, wherein the AGC control means obtains a gain setting value indicated by the gain adjustment signal by calculation. And a gain set value storage means for storing, for each base station, a converged value of the gain set value calculated by the gain set value calculation means for each base station, and the gain set value calculation means includes the gain A new gain setting value is calculated using the gain setting value of the corresponding base station stored in the setting value storage means.

Therefore, while performing AGC control for each base station, the time (convergence time) required for adjusting the gain of the signal amplifying means so that the reception level becomes optimum can be shortened. Further, since the convergence time can be shortened, the error can be reduced by keeping the time for performing the AGC control constant. Furthermore, if the convergence time is constant, a wider dynamic range than before can be realized.

Further, the mobile terminal according to the present invention comprises the AGC control device according to claim 5. Since the mobile terminal is equipped with the AGC control device according to the present invention, the mobile terminal can obtain good reception characteristics.

[0018]

BEST MODE FOR CARRYING OUT THE INVENTION The AGC control device according to the present invention is
As shown in FIG. 1, it is used in a communication system that includes a base station 100 having the AGC control device and at least one mobile terminal 150 and that transmits and receives signals by a time division multiplexing method. When communication is performed between the base station 100 and the mobile terminal 150, the distance between the movable mobile terminal 150 and the base station 100 and the environment (walls, obstacles, reflectors) around the terminal are different from those of the mobile terminal 150. Since the AGC control device of the base station 100 changes depending on the position, the AGC control device of the base station 100 sets the gain of the amplifier provided inside so that the received signal level approaches the specified value before performing the quadrature demodulation (the base station 100 or the mobile terminal). It is adjusted every 150). That is, automatic gain control (AGC: Automatic Gain Control) is performed for each communication partner.
l) have done.

Further, in the present embodiment, the mobile terminal 150 is provided with the MAC-ID corresponding to the identifier in the claims which is the identification information of the terminal, and the signal transmitted from the mobile terminal 150 has this MAC-ID. The MAC-ID is included. Therefore, by referring to the MAC-ID included in the signal transmitted from mobile terminal 150, base station 100 can determine from which mobile terminal the signal is transmitted. Note that, as described above, since the multiplexing system of the communication system is a time division multiplexing system, the base station 100 communicates with different mobile terminals in the area for each frame.

Embodiments of the AGC control device of the present invention will be described below in detail with reference to the drawings. First, FIG. 2 shows a configuration diagram of the base station 100 provided with the AGC control device of the present embodiment. As shown in FIG.
Is an antenna 101 and an LNA (Low Noise Amplifier)
103, a mixer 105, and local oscillators 107 and 113
And an amplifier 1 corresponding to the signal amplifying means in the claims.
09, the quadrature demodulator 111, the A / D unit 115, and the AG
An AGC control section 117 corresponding to C control means and a D / A section 119 are provided.

Hereinafter, the amplifier 109 and the AGC control unit 117, which are the constituent elements of the AGC control device of this embodiment, will be described.
Will be described. First, the amplifier 109 amplifies a reception signal from the mobile terminal 150, whose gain can be changed by a signal from the outside. The signal from the outside is specifically the D / A output from the AGC controller 117.
Since it is a converted signal, the gain of the amplifier 109 is A
It can be said that it is adjusted by the GC control unit 117. Further, the AGC control unit 117 outputs a signal for adjusting the gain of the amplifier 109 based on the signal level of the received signal (hereinafter referred to as “gain adjustment signal”). Note that, hereinafter, a series of processes such as adjusting the gain of the amplifier 109 based on the reception level is referred to as “AGC control”.
Say.

The internal structure of the AGC controller 117 will be described in detail below with reference to FIG. In the figure, the same parts as those of the conventional AGC controller 17 are designated by the same reference numerals.

As shown in FIG. 3, the AGC controller 117
Is the reception level measuring unit 201 and the target level storage unit 20.
3, a subtraction unit 205 and a calculation unit 207 corresponding to the gain setting value calculation unit in the claims, a memory unit 209 corresponding to the gain setting value storage unit, and a conversion unit 211. . The reception level measuring unit 201 measures the reception level from the I signal and the Q signal obtained as a result of quadrature demodulation by amplifying the reception signal with the amplifier 109. The reception level A is obtained by "I ² + Q ² ". Further, the target level storage unit 203 stores the target level B of the reception level. In addition, the subtraction unit 205
Is to subtract the reception level A obtained by the reception level measuring unit 201 from the target level B stored in the target level storage unit 203 to obtain the subtraction value C (= B−A).

The calculation unit 207 calculates the gain setting value indicated by the gain adjustment signal. More specifically, the n + 1-th gain setting value D _{n + 1} is n
Th gain setting value D _n and update coefficient k (0 <k <1)
And the n-th subtraction value C _n obtained from the subtraction unit 205, the calculation formula of D _{n + 1} = D _n + k × C _n is obtained. The gain setting value D _{n + 1} thus obtained is stored in the memory unit 209 so as to correspond to the corresponding MAC-ID. However, the AGC control accompanied by the calculation is performed a plurality of times per frame, and the memory unit 209 stores the gain setting value D (convergence value) finally obtained in one frame. On the other hand, the gain setting value D obtained on the way is temporarily stored in a cache memory or the like (not shown) different from the memory unit 209, and is used in the next AGC control calculation in the same frame.

The update coefficient k is a coefficient indicating how much the subtracted value C is reflected in the gain setting value D _{n + 1} .
Since the subtraction value C is the difference between the reception level A and the target level B, the amplifier 10 is optimized to optimize the reception level depending on how much the subtraction value C is reflected in the gain setting value D _{n + 1.}
The time required for adjusting the gain of 9, that is, the length of the convergence time changes. For example, when the update coefficient k is close to “0”, the convergence time becomes long.

The memory unit 209 also includes a mobile terminal 150.
Latest gain setting value D obtained when communicating with
The (convergence value) is stored for each mobile terminal. For example, as shown in FIG. 4, the latest gain setting value “20” corresponds to the mobile terminal whose MAC-ID is “1”, and these pieces of information are stored in the memory address “1”. Also,
The latest gain setting value "47" corresponds to the mobile terminal with the MAC-ID "2", and these pieces of information are stored in the memory address "2".

In addition, the conversion unit 211 uses the gain setting value D obtained by the calculation unit 207 as the D / A unit 1 in the subsequent stage shown in FIG.
It is for adjusting to the 19 format, in other words, for generating a gain adjustment signal from the gain setting value D in accordance with the characteristics of the amplifier 109. The signal output from the AGC control unit 117 is the D / A unit 119.
After being converted from a digital signal to an analog signal by, the signal is supplied to the amplifier 109.

The operation of the AGC controller will be described below. Note that specific numerical values are used as variables for obtaining the gain setting value D, for example. First, the target level B =
It is set to -40 dBm, and M is stored in the memory unit 209.
Latest gain setting value D _n = corresponding to AC-ID “1”
When +20 is stored, the reception level A = −50d of the signal transmitted from the mobile terminal whose MAC-ID is “1”.
When it is measured as Bm, the subtraction unit 205 obtains the subtraction value C = + 10 dB from the formula C = B−A. The calculation unit 207 calculates k
= 0.5, the n + 1-th gain setting value D _{n + 1} = D _n + k × C _n is calculated as D _{n + 1} = 20 + 0.5 ×
Calculate 10 = 25.

Although depending on the frame format, the time during which AGC control can be performed in one frame is limited. Therefore, the AGC control unit 117 obtains D _{n + 1} , then obtains D _{n + 2,} and so on, so that the reception level approaches the specified value during the time, in other words, the subtraction value C.
The gain of the amplifier 109 is adjusted so that is close to “0”. Among the values thus obtained, the gain setting value D (convergence value) finally obtained is the corresponding MAC-ID “1”.
Is stored in the memory unit 209 in correspondence with.

The above-described AGC control is an operation performed by the base station 100 at a predetermined time in one frame.
After that, user data is transmitted between 0 and the mobile terminal 150. The sequence up to user data transmission will be described below with reference to FIG. First, the base station 100 notifies the mobile terminal 150 within the area of control information. When the mobile terminal 150 makes a communication request to the base station 100, the base station 100 sends a MAC-ID to the mobile terminal 150.
And the mobile terminal 150 responds to the request by the base station 1
00-transmits the MAC-ID. Next, the mobile terminal 150
Makes a band request to the base station 100, and if the base station 100 informs the mobile terminal 150 of the band allocated in response to this request, communication in the band becomes possible, so the mobile terminal 150 and the base station 100 User data is transmitted to and from.

As described above, the AGC of this embodiment
According to the control device, the AGC control unit 117 causes the memory unit 20 to
9, the memory unit 209 stores the latest gain setting value D (convergence value) obtained when communicating with the mobile terminal 150 for each mobile terminal. Therefore, the calculation unit of the AGC control unit 117 is provided. 207 can be used for the calculation for reading the gain setting value D of the corresponding mobile terminal from the memory unit 209 and obtaining the next gain setting value D. In this way, since AGC control can be performed individually for each mobile terminal, a base station equipped with the AGC control device of this embodiment can obtain good reception characteristics.

Further, as shown in FIG. 6, conventionally, the gain setting value D is obtained from the state where the amplitude level of the received signal is "0", so that the convergence time becomes long, and conversely, if the convergence time is shortened, the dynamic setting becomes dynamic. The range has narrowed and the error has increased. However, in this embodiment,
By using the gain setting value D stored in the memory unit 209, the convergence time can be shortened. That is, the pull-in of AGC (automatic gain control) can be accelerated. Further, since the convergence time can be shortened, the error can be reduced by keeping the time for performing the AGC control constant.

On the other hand, if the convergence time is constant, a wider dynamic range than before can be realized. For example, when the target level B is -40 dBm, the conventional dynamic range of -60 to -20 dBm can be set to -70 to -10 dBm according to the present embodiment.

In the present embodiment, the case where the AGC control device is provided in the base station 100 has been described, but as another embodiment, the AGC control device is provided in the mobile terminal 15.
It may be set to 0. At this time, the base station 100 in the above description is replaced with the mobile terminal 150, and the mobile terminal 15
0 is read as the base station 100. In the other embodiment, since the AGC control can be individually performed for each base station, the mobile terminal equipped with the AGC control device can obtain good reception characteristics.

[0035]

As described above, according to the AGC control device of the present invention, while performing AGC control for each mobile terminal,
The time (convergence time) required to adjust the gain of the signal amplifying means so that the reception level becomes optimum can be shortened. Further, since the convergence time can be shortened, the error can be reduced by keeping the time for performing the AGC control constant.
Furthermore, if the convergence time is constant, a wider dynamic range than before can be realized.

[Brief description of drawings]

FIG. 1 is an explanatory diagram showing a communication system including a base station having an AGC control device and a mobile terminal.

FIG. 2 is a configuration diagram of a base station provided with an AGC control device according to an embodiment.

FIG. 3 is a block diagram showing an internal configuration of an AGC control unit according to an embodiment.

FIG. 4 is an explanatory diagram showing a data configuration of a memory unit included in the AGC control unit according to the embodiment.

FIG. 5 is a sequence chart illustrating processing up to user data transmission.

FIG. 6 is an explanatory diagram illustrating characteristics of the AGC control unit according to the related art and the present embodiment.

FIG. 7 is a block diagram showing an internal configuration of a conventional AGC control unit.

[Explanation of symbols]

100 base stations 101 antenna 103 LNA 105 mixer 107,113 Local oscillator 109 amplifier 111 Quadrature demodulator 115 A / D section 117 AGC controller 119 D / A section 150 mobile terminals 201 Reception level measurement unit 203 Target Level Storage Unit 205 Subtractor 207 Operation unit 209 memory section 211 Converter

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Shinichi Kugo             3-1, Tsunashima-Higashi 4-chome, Kohoku-ku, Yokohama-shi, Kanagawa             Matsushita Communication Industry Co., Ltd. (72) Inventor Yoshihiro Adachi             3-1, Tsunashima-Higashi 4-chome, Kohoku-ku, Yokohama-shi, Kanagawa             Matsushita Communication Industry Co., Ltd. (72) Inventor Daichi Imamura             3-1, Tsunashima-Higashi 4-chome, Kohoku-ku, Yokohama-shi, Kanagawa             Matsushita Communication Industry Co., Ltd. (72) Inventor Hiroaki Sudo             3-1, Tsunashima-Higashi 4-chome, Kohoku-ku, Yokohama-shi, Kanagawa             Matsushita Communication Industry Co., Ltd. F-term (reference) 5J100 JA01 LA00 LA08 LA11 QA01                       SA02                 5K061 BB12 CC52 JJ07                 5K067 AA13 AA33 EE02 EE10 GG11                       HH21

Claims (6)

[Claims] 1. An AGC control device for performing AGC control for each mobile terminal, the signal amplification means capable of changing a gain for amplifying a received signal from the mobile terminal, and a gain adjustment for adjusting a gain of the signal amplification means. AGC control means for supplying a signal to the signal amplification means,
The AGC control means includes a gain setting value calculating means for calculating a gain setting value indicated by the gain adjustment signal, and a convergence value of the gain setting value calculated by the gain setting value calculating means within a predetermined time. Gain setting value storage means for storing for each mobile terminal, wherein the gain setting value calculation means uses the gain setting value of the corresponding mobile terminal stored in the gain setting value storage means to generate a new value. An AGC control device characterized by calculating a gain setting value. 2. The gain setting value calculation means stores the signal level of the reception signal amplified by the signal amplification means, a target level of the signal level of the reception signal, and the gain setting value storage means. The AGC control device according to claim 1, wherein a new gain setting value is calculated based on the gain setting value of the corresponding mobile terminal. 3. The mobile terminal is provided with an identifier for identifying the terminal, and the signal transmitted from the mobile terminal includes the identifier. AG listed
C control device. 4. The AG according to claim 1.
A base station equipped with a C control device. 5. An AGC control device for performing AGC control for each base station, the signal amplifying means capable of changing a gain for amplifying a received signal from the base station, and a gain adjustment for adjusting a gain of the signal amplifying means. AGC control means for supplying a signal to the signal amplification means,
The AGC control means includes a gain setting value calculating means for calculating a gain setting value indicated by the gain adjustment signal, and a convergence value of the gain setting value calculated by the gain setting value calculating means within a predetermined time. A gain setting value storage means for storing each base station, wherein the gain setting value calculation means uses the gain setting value of the corresponding base station stored in the gain setting value storage means to obtain a new value. An AGC control device characterized by calculating a gain setting value. 6. A mobile terminal comprising the AGC control device according to claim 5.