KR20020009217A - Apparatus for controlling power of sending signal in wireless local loop of wide-band cdma - Google Patents

Abstract

PURPOSE: A transfer power control apparatus in a radio local loop system of a broadband CDMA method is provided to output a signal desired by a user by automatically controlling an SINR(Signal Interference and Noise power Rate) requested by the user. CONSTITUTION: When a signal is outputted as a certain power P0(t)(dB) from a radio connecting unit modem(130), a channel loss as much as a value 'G' is generated due to a restriction of a transmission distance, and a Nt(t)(dB) is added to the signal where the channel loss is generated due to the channel environment is added and transmitted. Then, a radio unit modem(100) measures a signal interference-to-noise ratio by using the signal by means of an SINR measuring unit(101), and transmits the measured value to the first adder(103). At this time, the data outputted form the first adder(103) has a negative value. The first adder(103) receives a signal of an SINR output unit(120) that outputs a value of a signal requested from a subscriber. The first adder(103) adds the two signals and outputs a corresponding value to the second adder(105). A BER value stored in the second register is read from a BER output unit(111B) and outputted to an SINR compensating unit(111A). The SINR compensating unit(111A) computes an SINR value to be compensated by using the value outputted from the BER output unit(111B), and outputs the SINR value to the second adder(105) by using the computed value. Then, the second adder(105) adds the two values and inputs it to an energy measuring unit(107) for measuring an energy. Then the energy measuring unit(107) computes an energy value(e1).

Description

Transmission power control device in wireless local loop system of wideband code division multiple access method {APPARATUS FOR CONTROLLING POWER OF SENDING SIGNAL IN WIRELESS LOCAL LOOP OF WIDE-BAND CDMA}

The present invention relates to a wireless local loop system of a wideband code division multiple access scheme, and more particularly, to an apparatus for controlling the output of a signal in a wireless local loop system.

Typically, in a wireless system, when transmitting data, power to be transmitted is controlled according to a state of a channel. By controlling the transmission power in this way, it is possible to safely transmit and receive data at an appropriate power. However, in the wireless local loop system of the wideband code division multiple access method, power transmission is controlled using a very simple method. This will be described below. In order to satisfy the desired bit error ratio (hereinafter referred to as BER) in the code division multiple access system when transmitting data in the pulse code modulation (PCM) method used in transmission, signal interference Power is controlled by setting the ratio of Signal Interference & Noise Power Ratio (hereinafter referred to as SINR). In the case of controlling the power of a signal to be transmitted as described above, the SINR required under a given BER condition shows very different results depending on the state of the channel. That is, in a channel in which data is being transmitted and received in a continuously operated mode, the channel cannot be directly estimated accurately. Therefore, it is necessary to estimate the channel indirectly and change the SINR accordingly to control the power to satisfy the required BER.

However, power control in the wireless local loop system of the wideband code division multiple access method currently in use simply uses a closed power control method, and thus cannot satisfy the communication quality desired by the user. That is, there is a problem that a high quality communication service desired by a user is impossible by controlling power only according to a preset sinr.

Accordingly, an object of the present invention is to provide a signal output control apparatus capable of automatically outputting a desired signal by automatically adjusting SINR required by a user in a wireless local loop system of a wideband code division multiple access method.

Another object of the present invention is to provide an apparatus capable of providing a high quality communication service in a wireless local loop system of a wideband code division multiple access method.

The apparatus of the first embodiment according to the present invention for achieving the above objects is a power control device of the transmission signal in a wireless local loop system of the wideband code division multiple access method, extracts and measures the SINR from the wireless signal and measure the measured value An SINR measuring unit for outputting, an SINR compensating unit for compensating and outputting SINR according to a Bit Error Rate (BER), an SINR output unit for outputting a pre-calculated SINR value, a signal of the SINR output unit and the An adder for adding and outputting the output of the SINR measuring unit and the output of the SINR compensating unit, a first energy calculating unit for calculating a first energy value using the output of the adding unit, a threshold and automatic gain control of the automatic gain control; The second energy calculator calculates the second energy using the difference of the values, and receives the measured values of the first energy calculator and the second energy calculator to generate a comparison value. A comparison determination unit for comparing the output of the comparison data generation unit, the output of the comparison data generation unit with a predetermined value and outputting a power control value, and delaying and outputting the power control value output from the comparison determination unit for a predetermined time. It is characterized by consisting of a delay unit.

The apparatus according to the second embodiment of the present invention for achieving the above object is a power control device of the transmission signal in a wireless local loop system of the wideband code division multiple access method, extracts and measures the FQI from the radio signal An FQI measuring unit for outputting a calculated value, an SINR measuring unit for measuring an SINR value using the output of the FQI measuring unit, an SINR output unit for outputting a pre-calculated SINR value, a signal and the SINR measuring unit for the SINR output unit An adder for adding and outputting a negative output, an energy calculator for calculating an energy value using the output of the adder, a weight multiplier for multiplying and outputting an energy value output from the energy calculator, and a weight factor; A first comparison determination unit for comparing the output of the weight multiplication unit with a predetermined value and outputting a power control value, and the first comparison determination unit An adder which adds and outputs a value of the output of the adder and a value output before a predetermined time; Characterized in that it comprises a determination unit.

1 is a block diagram for measuring an error rate for each channel from a received signal according to a preferred embodiment of the present invention;

2 is a block diagram illustrating transmission power control of a reverse link according to an embodiment of the present invention;

3 is a block diagram for forward power control of a wireless local loop system according to another embodiment of the present invention.

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

1 is a block diagram for measuring an error rate for each channel from a received signal according to a preferred embodiment of the present invention. Hereinafter, a configuration and an operation according to the present invention will be described in detail with reference to FIG. 1.

The signal received by the wireless receiver on the base station side of the broadband wireless local loop system is multiplied by the PN code. The signal is multiplied by the PN code, and is stored in the first register 10 in a state where despreading is performed through an orthogonal code. Data stored in the first register 10 is input to respective deinterleavers 20, 30, 40, and 50 corresponding to each channel. Since the configuration after each of the deinterleavers 20, 30, 40, and 50 is the same, only the configuration in which data of the first channel is processed will be described.

The deinterleaver 20 recovers the interleaved data at the time of data transmission and outputs the interleaved data to the input terminal of the depuncture device 21. Since the input signal is a punctured signal at the time of transmission, the depuncturer 21 converts the received signal into a symbol through its reverse process. The deinterleaver 20 and the depuncturer 21 operate under the control of a control unit (not shown) for controlling the wireless unit, and the control unit uses a microprocessor or a digital signal processing processor (DSP). Can be implemented. The output converted into a symbol in the depuncturer 21 is divided into two, one output is input to the Viterbi decoder 22, and the other output is input to the detector 24. Accordingly, the Viterbi decoder 22 decodes the data input as a symbol and converts the data into data. When this decoding is performed, an error generated during transmission is restored. The recovered data is entered into the next block for processing so that it can be transmitted to the transmission equipment or other wired or wireless subscribers. The subsequent steps are omitted in the description of the present invention because they may obscure the subject matter. In addition, the data decoded by the Viterbi decoder 22 is input to a convolutional encoder 23. The convolutional encoder 23 recodes and outputs the data from which the error is restored.

In addition, the signal input from the detector 24 is detected according to a predetermined level value, and the signal of the predetermined level value or more is input to the delay unit 23. The delayer 23 outputs the input signal after delaying by the time coded and encoded by the Viterbi decoder 22 and the convolutional encoder 23. The signal output from the delayer 23 and the two signals output from the convolutional encoder 23 are input to the comparator 26. The comparator then compares the two signals and outputs the compared values. That is, when two signals are different, a value according to an error is output, and when the two signals are identical, a signal is outputted that has the same value. The output of this comparator 26 is input to the BER meter 27. Therefore, the BER measuring device 27 outputs data according to the error rate to the second register 60 using the same. The second register 60 stores the signal received from the BER measuring instruments 27, 37, 47, 57 for each channel. By using the values output from the BER measuring instruments 27, 37, 47, 57, it is possible to accurately determine the state of each continuous channel.

2 is a block diagram illustrating transmission power control of a reverse link according to an embodiment of the present invention. Hereinafter, a configuration and an operation for transmission power control of a reverse link according to the present invention will be described in detail with reference to FIG. 2.

First, reference numeral 100 is a block diagram of a configuration for power control of a wireless local loop system base station, and reference numeral 130 is a block configuration for power control of a terminal. In the following description, reference numeral 100 is referred to as a radio part modem, and reference numeral 130 is referred to as a radio interface modem.

The signal output from the wireless connection modem 130 with a predetermined power P ₀ [t] (dB) causes channel loss as much as G value due to the limitation of the transmission distance, and N due to the channel environment such as interference with other radio waves. This is added to the signal with this channel loss by _t [t] (dB) and transmitted. The radio modem 100 receiving the signal then measures the ratio of signal interference to noise in the SINR measurement unit 101 using this signal. The measured value is output to the first adder 103. In this case, the data output to the first adder 103 may be output with a negative value. The first adder 103 receives a signal from the SINR outputter 120 that outputs the value of the signal requested from the subscriber. The first adder 103 adds the two signals and outputs the corresponding value to the second adder 105. The BER value calculated by the configuration of FIG. 1 and stored in the second register 60 is read by the BER output unit 111B and output to the SINR compensation unit 111A. The SINR compensator 111A calculates an SINR value to be compensated using the value output from the BER output 111B. The SINR value is output to the second adder 105 using the calculated value. Then, the second adder 105 adds the two input values to the energy measurer 107 which measures energy. The energy measuring unit 107 then calculates an energy value e ₁ . In this case, the calculated value may be calculated by Equation 1 below.

The energy value calculated by Equation 1 is input to the determination data calculator 109 that outputs power control determination data. The determination data calculation unit 109 then calculates a value of γ. This γ value is calculated by the following formula (2).

In Equation 2, PC refers to a power control value, and T _p is calculated as a value delayed by a predetermined time with a value of time delayed when calculating the power control value.

Meanwhile, a predetermined threshold value of the automatic gain adjustment value and the automatic gain adjustment value is added by the third adder 115. The calculated value is input to the second energy calculator 113. The second energy calculator 113 sets the second energy value e ₂ to 0 when the sum δ of the two automatic gain control values is greater than zero, otherwise sets the second energy value e _2. Is the sum of the two auto gain adjustment values (δ). When the first energy value e ₁ measured by the energy measuring unit 109 is smaller than a predetermined comparison value ε, and the second energy value e ₂ has a value of “0”, The specific gravity value is output, and if not, the value obtained by multiplying the calculated first energy value e _{1 by} a predetermined first weight value W ₁ and another predetermined predetermined value by the second energy value e ₁ . The value obtained by multiplying the second weight value of w ₂ is added and used as judgment data. The determination data is input to the determination unit 117 to output a value of 1 when the value is greater than the preset value, and a value of -1 when the value is smaller than the preset value. The power is controlled in the reverse direction through the output value.

3 is a block diagram for forward power control of a wireless local loop system according to another embodiment of the present invention. Hereinafter, the present invention will be described in detail with reference to FIG. 3.

The FQI measuring unit 201 measures the phase of the received signal and inputs it to the SINR measuring unit 202. Then, the SINR measurement unit 202 receives and measures this and inputs it to the first adder 203. Then, the first adder 203 adds the SINR value output from the SINR output unit 200 and the measured SINR value and inputs it to the first calculator 204. Then, the first calculator 204 calculates the equation as shown in Equation 3 using the input data and outputs it.

In Equation 3, e is a value of power, and the data calculated by the method as shown is input to the multiplier 205 to multiply the weight factor ω. Then, the multiplier 205 multiplies the input power value by the weight factor ω and inputs it to the data determination unit 206. The data determination unit 206 is a synchronized data determination unit having a dynamic range. In this way, the data determined and output by the data determination unit 206 is input to the adder 209. The adder 209 is delayed by Τ _P to the data output from the adder and added to the input value. Then, the added data is input to the data determination unit 209 located in the next stage to control the transmission power of the terminal. The data controlled in this way is lost by the loss value G of the radio channel environment, and is input to the terminal with interference by the power value N _t [t] due to the interference.

Then, the wireless access modem 230 of the terminal receives data from the radio modem 200 and generates power according to the quality of the frame through the SINR measurement unit 231 and the frame indicator generator 232 to generate power. Control.

As described above, there is an advantage in that power of a signal transmitted in a wireless local loop system of a wideband code division multiple access method can be efficiently controlled even in continuous data.

Claims (5)

An apparatus for controlling power of an outgoing signal in a wireless local loop system using a wideband code division multiple access method, An SINR measurement unit for extracting and measuring SINR from a wireless signal and outputting the measured value; A SINR compensator for compensating and outputting SINR according to a bit error rate (BER); An SINR output unit for outputting a pre-calculated SINR value, An adder configured to add and output the signal of the SINR output unit, the output of the SINR measurement unit, and the output of the SINR compensator; A first energy calculator configured to calculate a first energy value using an output of the adder; A second energy calculator configured to calculate a second energy using a difference between the threshold of the automatic gain control and the automatic gain control value; A comparison data generator which receives the measured values of the first energy calculator and the second energy calculator and generates a comparison value; A comparison determination unit which outputs a power control value by comparing the output of the comparison data generation unit with a predetermined value; And a delay unit for delaying and outputting the power control value output from the comparison determination unit for a predetermined time. The method of claim 1, wherein the first energy calculation unit, Transmission signal power control apparatus in a wireless local loop system of a wideband code division multiple access wireless system, characterized in that calculated by Equation (4). The method of claim 1 or 2, wherein the second energy calculation unit, Transmission signal power control apparatus in a wireless local loop system of a wideband code division multiple access wireless system, characterized in that calculated by Equation (5). In Equation 5, PC is a power control value, and T _p is a value of time delayed when calculating the power control value. An apparatus for controlling power of an outgoing signal in a wireless local loop system using a wideband code division multiple access method, An FQI measurement unit which extracts and measures an FQI from a wireless signal and outputs the measured value; An SINR measuring unit measuring an SINR value using an output of the FQI measuring unit; An SINR output unit for outputting a pre-calculated SINR value, An adder which adds and outputs the signal of the SINR output unit and the output of the SINR measurement unit; An energy calculator for calculating an energy value using the output of the adder; A weight multiplier for multiplying and outputting an energy value output from the energy calculator to a weight factor; A first comparison determiner configured to compare the output of the weight multiplier with a predetermined value and output a power control value; An adder which adds and outputs the output of the first comparison determiner and a value output before a predetermined time; A delay unit for delaying the output of the addition unit for a predetermined time; And a power control determiner configured to determine a power control value by using the output of the adder. The method of claim 4, wherein the first calculation unit, Transmission signal power control apparatus in a wireless local loop system of a wideband code division multiple access wireless system, characterized in that calculated by Equation (6).