JP4234900B2 - Terminal station for wireless communication system, base station for wireless communication system, wireless communication system, and reception field strength compensation method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a terminal station that communicates with a base station, and in particular, has a receiver capable of detecting received field strength using a logarithmic amplifier, and can reduce errors in received field strength detection accuracy due to differences in signal waveforms. The present invention relates to a terminal station for a wireless communication system, a base station for a wireless communication system, a wireless communication system, and a reception field strength compensation method.
[0002]
[Prior art]
The CDMA (Code Division Multiple Access) system as a multiple access wireless communication system is a multiple access system that inherently has confidentiality and interference resistance and enables effective use of radio frequencies. It is applied to various communication systems. In recent years, this CDMA system is called a transmission quality degradation (hereinafter referred to as a near-far problem) due to a significant change or a difference in the position of each terminal station located in a wireless communication zone formed by a wireless base station. ) Is now applicable to mobile communication systems.
[0003]
Software radios are also being researched and are being applied as devices for illegal radio crackdown. This software defined radio is a transmitter / receiver that can support multiple modulation schemes. Software that supports multiple modulation schemes can be rewritten to a minimum amount of hardware by downloading etc. whenever the modulation scheme is changed. It is realized.
[0004]
Furthermore, in recent years, there has been an increasing demand for improving the detection accuracy of received signal strength indicators (RSSI) of these wireless devices. The reason why high detection accuracy is required is that transmission power is defined by system specifications. For example, in an N-CDMA (Narrow-Band CDMA) system, the relationship between average transmission power and average reception power is expressed by equation (1).
[0005]
Average transmission power (dBm) = − Average reception power (dBm) −Fixed value (dBm) (1)
In addition, in order to estimate the presence / absence of radio waves transmitted by illegal wireless devices from RSSI, there is a high demand for software wireless devices with respect to detection accuracy of RSSI, and the detection accuracy is usually several dB or less. It is demanded.
[0006]
Conventionally, in this RSSI detection method, a logarithmic amplifier included in an RSSI detection unit of a receiver (a receiver of a base station and a terminal station) generates a voltage corresponding to the RSSI, and an RSSI and RSSI detection value (described above) Output voltage), and the RSSI is estimated and detected using a memory stored in advance.
As is well known, the RSSI detector is mainly provided in a high-frequency circuit, and an antenna mark is displayed on the display of the mobile phone based on the estimated RSSI.
[0007]
In particular, according to the CDMA system, a method of estimating RSSI using a memory having a single correspondence table is generally used regardless of the number of multiplexed reception channels.
FIG. 13 is a diagram showing an example of the characteristics of the input electric field (input electric field strength) and the output voltage of the logarithmic amplifier, and the output voltage of the characteristic curve shown in FIG. 13 indicates the detected value of the input electric field strength. An example of data in the memory table is shown in FIG.
[0008]
FIG. 14 is a diagram showing the correspondence between the output voltage and RSSI. In the method of obtaining data shown in FIG. 14, a digital value obtained by analog / digital conversion (hereinafter referred to as A / D conversion) of an output voltage may be abbreviated as an input address (hereinafter referred to as input address) of a memory. The output voltage written in the memory is obtained. That is, a receiver that has received an electric field whose reception field strength is unknown can estimate the RSSI by using the output voltage of the RSSI detector as an input address.
[0009]
As an example, in FIG. 14, when the output voltage of the RSSI detector is, for example, 0.84 V (volts), the input address is 50 (HEX, which represents a hexadecimal number). In this case, RSSI (data and display) Is estimated to be -50 dBm. Similarly, if the output voltage of the RSSI detector is 1.26V, it is estimated that the RSSI is −30 dBm.
[0010]
Further, if the data values held in the memory table are used as they are, the detection accuracy deteriorates. Therefore, a method of interpolating other data between the RSSI data by linear approximation is used. When this linear approximation is used, in the above example, the output voltages of 0.84 V and 1.26 V are −53 dBm and −32 dBm, respectively, and the detection accuracy is improved.
[0011]
[Problems to be solved by the invention]
However, when the CDMA method is used, an error in RSSI detection occurs, and an error based on the difference in multiplexing number also occurs.
First, RSSI using a logarithmic amplifier will be described.
The output of a normal amplifier used as a logarithmic amplifier used for RSSI detection depends not on the input voltage but on the input intermediate frequency band signal waveform, and the output voltage has a different offset due to the difference in the signal waveform. Arise.
[0012]
FIG. 15 is a block diagram showing an example of the circuit configuration of the logarithmic amplifier. The logarithmic amplifier 100 shown in FIG. 15 includes a plurality of operational amplifiers 101 and an adder (Σ) 102. When the input signal (input voltage) is a DC (Direct Current) signal or a rectangular wave (rectangular wave signal), assuming that the input signal is Vin and the output signal (output voltage) is Vout, the transfer function of the logarithmic amplifier 100 is , (2).
[0013]
Vout = Vy * Log (Vin / Vx) (2)
Here, Vx and Vy are fixed voltages that determine the scaling of the logarithmic amplifier 100, respectively, where Vx represents an intercept voltage and Vy represents a slope voltage. * And Log represent multiplication and natural logarithm, respectively.
The intercept and slope are derived from the intercept and slope of the regression line used for traffic analysis, and are statistical parameters when designing the system specifications.
[0014]
When the logarithmic amplifier 100 shown in FIG. 15 is used for RSSI detection, an offset occurs in the output voltage when the input signal is other than a DC signal or a rectangular wave.
FIG. 16 is a diagram showing output voltage offset values relating to various input signal waveforms. The error (dB) with respect to the DC signal shown in FIG. 16 represents an error when the input signal waveform (input waveform) is a sine wave, a triangular wave, or the like and the input waveform is a DC signal. Yes. That is, as the output voltage such as a sine wave, a voltage having a value smaller than that of the DC signal is output.
[0015]
Next, in the CDMA system, when the receiving side receives a radio signal channel-multiplexed on the same carrier (same frequency), the received signal waveform changes as the number of multiplexing increases. Therefore, similarly to the above, an offset occurs in the output voltage, and an RSSI detection error occurs.
FIG. 17 is a diagram illustrating an example of the characteristics of the multiplexing number and the RSSI detection value in the N-CDMA system. The three characteristic curves shown in FIG. 17 are for different multiplex numbers (1 code, 10 code, and 60 code). The deviation (interval) between these characteristic curves is an RSSI detection error, and an error of about 4 dB is generated for one code (single code).
[0016]
On the other hand, in a multimode terminal that supports multimode (corresponding to a plurality of communication schemes) as in the TACS + N-CDMA system, an output voltage offset similar to the above occurs, so the received electric field and RSSI detection in the RSSI detector The value (output voltage) must be estimated. For this reason, it is necessary to prepare a plurality of estimation memories, and there is a problem that the circuit scale increases.
[0017]
In addition, in a wireless communication system that supports a plurality of modulation schemes, the number of memories corresponding to the number of modulation schemes is required, and the circuit scale increases.
Furthermore, in the CDMA system, the RSSI is estimated by using a memory having only a single table regardless of the number of multiplexed channels, so that there is a problem that an error in RSSI detection occurs depending on the number of multiplexed channels.
[0018]
In addition, as described with reference to FIG. 15, a normal device used as the logarithmic amplifier 100 is not an input voltage but an output with respect to an input signal waveform, and the signal waveform causes an offset in the output voltage. . Therefore, the output voltage has a problem that an error occurs depending on the number of multiplexed base stations in the CDMA system. Further, in a wireless communication system that supports a plurality of modulation schemes, there is a problem that an error occurs due to the modulation schemes.
[0019]
The present invention was devised in view of such problems, and in a wireless communication system using a code division multiple access communication system, avoids an increase in circuit scale and improves received electric field strength detection accuracy. An object of the present invention is to provide a terminal station for a wireless communication system, a base station for a wireless communication system, a wireless communication system, and a reception field strength compensation method capable of detecting an accurate received field strength.
[0020]
[Means for Solving the Problems]
  For this reason, the terminal station for the wireless communication system of the present invention generates and outputs data to be transmitted including control data and information data,Correction amount of detection error of received electric field strength on the receiving side due to multiplexing number or modulation methodOutput from the compensation parameter generator and the compensation parameter generatorCorrection amountA coder unit that encodes the data to be transmitted output from the data generation unit and outputs encoded data, and a first unit that converts the encoded data output from the coder unit into a radio frequency and outputs a radio signal. It is characterized by having a radio part..
[0021]
Preferably, the coder unit may be configured to perform encoding using a code for identifying the own station and another station.
The compensation parameter generation unit can be configured as shown in the following (1-1) to (1-3).
(1-1) A multiplex number detector that detects and outputs a multiplex number indicating the number of transmission channels for the same carrier, and an electric field intensity correction amount corresponding to the multiplex number output from the multiplex number detector is used as a compensation parameter. First correction memory to be held.
[0022]
Here, the multiplexing number detection unit includes a plurality of holding units that hold the enable signal, a first counter that outputs a channel number corresponding to the enable signal, and a plurality of holdings that correspond to the channel number output from the first counter. An address output unit that outputs the address of each unit and a second counter that counts the number of enable signals held in each of the plurality of holding units may be provided.
[0023]
Further, the multiplexing number detection unit may be configured to output the enable number for each channel group obtained by dividing a plurality of transmission channels, and the transmission number of the transmission channel for the same carrier output from the data generation unit. A multiplex number memory that holds a multiplex number based on an address composed of a combination of enable signals indicating on / off may be provided.
[0024]
(1-2) A multiplex number detection unit that detects a multiplex number indicating the number of transmission channels for the same carrier and outputs the multiplex number as a compensation parameter.
In addition, the compensation parameter generation unit may include a first control unit that inputs the compensation parameters in the compensation parameter generation unit to the coder unit.
[0025]
MaThe base station for the wireless communication system of the present invention isCorrection amount of detection error of received electric field strength on the receiving side due to multiplexing number or modulation methodAnd a second radio unit that receives a radio signal including the transmitted data, outputs a reception main signal obtained by frequency-converting the radio signal, and a received electric field strength voltage for the radio signal, and outputs from the second radio unit A decoding unit that outputs a baseband signal resulting from the received main signal, received field strength data resulting from a received field strength voltage output from the second radio unit, andCorrection amountAnd a compensation parameter output unit for outputting the received electric field strength data output from the compensation parameter output unit,Correction amountAnd a data demodulating unit for outputting demodulated data based on the baseband signal output from the decoding unit and the corrected receiving field strength data output from the correcting unit It is characterized by being configured with.
[0026]
Preferably, the second radio unit may be configured to receive a code division multiplexed radio signal and output a received main signal and a received electric field strength voltage for the radio signal.
The compensation parameter output unit can be configured as shown in the following (2-1) to (2-3).
[0027]
(2-1) Corresponds to an estimation memory that holds reception field strength data corresponding to the reception field strength voltage output from the second radio unit, and a multiplexing number indicating the number of transmission channels for the same carrier from the reception main signal. A first correction amount output unit that outputs the electric field intensity correction amount as a compensation parameter.
In addition, the first correction amount output unit may be configured as an electric field strength correction amount extraction unit that extracts and outputs the electric field strength correction amount from the received main signal.
[0028]
(2-2) An estimation memory that holds reception field strength data corresponding to the reception field strength voltage output from the second radio unit, and a multiplex number indicating the number of transmission channels for the same carrier are output from the reception main signal. A multiplex number receiving unit and a second correction amount output unit that outputs, as a compensation parameter, an electric field strength correction amount corresponding to the multiplex number output from the multiplex number receiving unit.
[0029]
In addition, the second correction amount output unit may be configured by a second correction memory that holds an electric field intensity correction amount corresponding to the multiplexing number.
(2-3) an estimation memory that holds reception field strength data corresponding to the reception field strength voltage output from the second radio unit, and a modulation parameter output unit that outputs a modulation parameter representing a modulation scheme from the reception main signal; A third correction amount output unit that outputs, as a compensation parameter, an electric field intensity correction amount corresponding to the modulation parameter output from the modulation parameter output unit.
[0030]
The third correction amount output unit may be configured by a third correction memory that holds an electric field intensity correction amount corresponding to the modulation parameter.
Furthermore, each of the compensation parameter output units described above can be configured to include a memory control unit that reads out received field strength data from the estimation memory based on the received field strength voltage and inputs the data to the correction unit. The control unit can be configured to output the received electric field strength data by a predetermined calculation based on the received electric field strength.
[0031]
In addition, the second radio unit can be configured to output the received electric field strength voltage using an amplifier whose input voltage and output voltage have desired characteristics.
Further, the estimation memory can be configured to hold the received electric field strength data in consideration of an offset value based on a reference wave having a predetermined characteristic for the received electric field strength voltage.
[0032]
  The wireless communication system of the present invention comprises a plurality of terminal stations that transmit and receive a radio signal modulated by a desired wireless communication method, and a base station that communicates with the terminal station.A data generation unit that generates and outputs data to be transmitted including control data and information data, and a compensation parameter that outputs a correction amount of the detection error of the reception electric field strength on the reception side caused by the multiplexing number or the modulation method A generation unit, a coder unit that encodes the correction amount output from the compensation parameter generation unit and the data to be transmitted output from the data generation unit and outputs encoded data, and the encoding output from the coder unit A first radio unit that converts data to a radio frequency and outputs a radio signal; and a base station that receives the radio signal and frequency-converts the radio signal; and a received electric field for the radio signal. A second wireless unit that outputs at least one of the intensity voltages; a decoding unit that outputs a baseband signal resulting from the received main signal output from the second wireless unit; Compensation parameter output unit for outputting received field strength data and correction amount due to received field strength voltage output from the line unit, and received field strength data and correction amount output from compensation parameter output unit And a data demodulating unit for outputting demodulated data based on the baseband signal output from the decoding unit and the corrected received field strength data output from the correcting unit. It is characterized by being configured.
[0033]
  In addition, the received field strength compensation method of the present invention includes:In a wireless communication system comprising a plurality of terminal stations that transmit and receive a radio signal modulated by a desired wireless communication method and a base station that communicates with the terminal station, the terminal station transmits for each one or a plurality of transmission channels A modulation step for modulating power data; a terminal station for a base station, a compensation parameter acquisition step for acquiring a correction amount of a detection error of a received electric field strength on the reception side caused by a multiplexing number or a modulation scheme; The terminal station is configured to include a transmission step of transmitting encoded data by encoding the data to be transmitted modulated in the modulation step and the correction amount acquired in the compensation parameter acquisition step. It is a feature.
[0034]
  Also, the received electric field strength compensation method of the present invention is:In a wireless communication system comprising a plurality of terminal stations that transmit and receive a radio signal modulated by a desired wireless communication method and a base station that communicates with the terminal station, the base station receives a signal caused by the multiplexing number or the modulation method. A reception step of receiving a radio signal having a correction amount of a detection error of a reception electric field strength on the side, a detection step of detecting a reception electric field strength of the radio signal received in the reception step, and a base station, A correction step for correcting a detection error of the received electric field strength based on the correction amount included in the radio signal received in the reception step and the received electric field strength detected in the detection step. It is a feature.
[0035]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings.
(A) Description of the first embodiment of the present invention
FIG. 1 is a configuration diagram of a radio communication system according to the first embodiment of the present invention. A wireless communication system 3 (hereinafter also referred to as system 3) shown in FIG. 1 uses a code division multiple access communication system (CDMA system), and is used for a mobile phone service as an example of a system. It is what This system 3 includes a plurality of terminal stations 1 that transmit and receive code division multiplexed radio signals (hereinafter also referred to as RF signals [Radio Frequency signals]), and a base station 2 that communicates with these terminal stations 1. It is configured with. Different codes are assigned to each other between the base station 2 and each terminal station 1 so that multiple access is possible. That is, the RF signal is transmitted and received after being modulated by the CDMA method.
[0036]
Here, each terminal station 1 performs correction for correcting RSSI (Receiving electric field strength) together with data to be transmitted including control data and information data such as voice or file data with respect to the base station 2, respectively. Parameters (hereinafter sometimes referred to as compensation parameters) are transmitted. The terminal station 1 multiplexes a plurality of transmission channels using the same carrier and transmits the multiplexed transmission channel to the base station 2.
[0037]
Here, an example of an aspect in which the terminal station 1 multiplexes a plurality of transmission channels is a method in which the terminal station 1 relays data transmitted by other terminal stations and transmits the data to the base station 2. Alternatively, the terminal station 1 can divide the data to be transmitted into a plurality of pieces, multiplex them, and transmit them to the base station 2.
In addition to the information data and control data transmitted from each terminal station 1, the base station 2 receives a compensation parameter and corrects the RSSI based on the compensation parameter. The base station 2 is connected to an exchange 4a having an exchange function, and can exchange data with a network 4b that accommodates another exchange (not shown).
[0038]
The terminal stations 1a and 1b, the base stations 2a and 2b, and the wireless systems 3a and 3b are respectively a modified example of the first embodiment, a modified example of the second embodiment, and a modified example of the second embodiment described below (hereinafter referred to as others). Will be abbreviated as an embodiment of the present invention).
FIG. 2 is a block diagram of the transmission unit of the terminal station 1 according to the first embodiment of the present invention. The terminal station 1 shown in FIG. 2 is a mobile station such as a mobile phone or a mobile terminal, for example. The main part of the transmission unit (transmission system) is a main control unit 14a, a baseband unit 15, a first The radio unit 12a and the antenna 11a are provided.
[0039]
The terminal station 1 has a receiving unit (reception system) in addition to the transmitting unit, and although not shown, the receiving unit outputs a high-frequency circuit that receives and processes a high-frequency signal, and outputs from the high-frequency circuit. A reception baseband signal processing unit that processes the received reception baseband signal, an audio processing circuit, a speaker, and the like. Since these are well-known ones, detailed description thereof is omitted. And terminal station 1 (1a, 1b), such as 1st Embodiment mentioned later and other embodiment, all has the receiving part. Hereinafter, for the terminal station 1 (terminal stations 1a and 1b to be described later), the transmission unit will be mainly described.
[0040]
First, the main control unit 14a controls each unit included in the baseband unit 15, the first radio unit 12a, and the terminal station 1. This function is realized by software in which a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), and the like cooperate.
Further, the baseband unit 15 generates a signal (information data and control data) to be transmitted in accordance with control by the main control unit 14a, and performs logical operations (logic processing) necessary for inputting to the first radio unit 12a. The data generation unit 17, the compensation parameter generation unit 5, the coder unit (CODER) 16, and the modulation unit 25 are provided. The signal in the baseband unit 15 is a digital signal, and the function of the baseband unit 15 is realized by, for example, an IC (Integrated Circuit), an LSI (Large Scale Integration), or the like.
[0041]
Here, the data generation unit 17 generates and outputs data to be transmitted including control data and information data. For this reason, the data generation unit 17 includes transmission data generation units 17-1 to 17-n that generate data to be transmitted for each of the terminal stations 1, as shown in FIG.
Further, the compensation parameter generation unit 5 (see FIG. 2) sets compensation parameters used for correction (compensation) of RSSI detection errors on the receiving side (base station 2) due to the difference in signal waveform. This is an output, and comprises a multiplexing number detector 18 and a first correction memory 19. Here, the multiplex number detection unit 18 detects and outputs the multiplex number indicating the number of transmission channels for the same carrier, and the first correction memory 19 determines the multiplex number output from the multiplex number detection unit 18. A corresponding electric field intensity correction amount (hereinafter sometimes referred to as a correction amount) is held as a compensation parameter.
[0042]
That is, the first correction memory 19 holds the multiplex number and the correction amount in association with each other, holds the multiplex number as an address in the address area, and detects the RSSI detection error that may occur in the base station 2. The correction amount (such as dBm) is read by the main control unit 14a. The function of the first correction memory 19 is realized by, for example, a ROM (Read Only Memory), and the same applies to other memories described later unless otherwise specified.
[0043]
Thereby, the RSSI compensation parameter in the base station 2 is transmitted from the terminal station 1, and the base station 2 can generate the RSSI that may be caused by the difference in the signal waveform due to the difference in the number of multiplexing based on the compensation parameter. The detection error can be corrected.
Next, a method of detecting the multiplex number in the multiplex number detection unit 18 will be described with reference to FIG.
[0044]
FIG. 3 is a block diagram of the multiplex number detection unit 18 and the data generation unit 17 according to the first embodiment of the present invention. The multiplex number detection unit 18 shown in FIG. 3 includes a first control unit 24 and an enable number counter 30.
Here, the first control unit 24 inputs the compensation parameters in the compensation parameter generation unit 5 (see FIG. 2) to the coder unit 16. Specifically, the first control unit 24 monitors and controls the multiplex number in the multiplex number detection unit 18, reads the correction amount based on the multiplex number from the first correction memory 19 using the multiplex number as an address, and stores the correction amount in the coder unit. 16 is input. Thereby, the correction amount can be controlled according to the communication status.
[0045]
The enable number counter 30 counts the number of enable signals indicating ON / OFF of the transmission channel for the same carrier, and includes transmission channel flip-flops (holding units: indicated as FF) 31a to 31a. 31d, 30d, an n-ary counter (first counter: n is an integer of 2 or more) 30a, a decoder (address output unit) 30b, and an n-ary counter (second counter) 30c.
[0046]
Here, flip-flops 31a, 31b, 31c,..., 31d hold enable signals, respectively, and transmission data generation units 17-1, 17-2, 17-3,. The enable signal to -n is latched. The n-ary counter 30a outputs a channel number corresponding to the enable signal, and the decoder 30b outputs the addresses of a plurality of flip-flops 31a to 31d corresponding to the channel number output from the n-ary counter 30a. Further, the n-ary counter 30c counts the number of enable signals held in each of the plurality of flip-flops 31a to 31d.
[0047]
As a result, the count value of the n-ary counter 30a is sequentially decoded, and disable signals (operation stop signals) are sequentially generated for the flip-flops 31a to 31d other than the transmission channel, and the disabled flip-flops. The n-ary counter 30c is sequentially incremented by the number of flip-flops other than 31a to 31d.
[0048]
When the count cycle (1 to n) of the n-adic counter 30a ends, the count value (the number of enable signals) of the n-adic counter 30c at that time is output as the transmission channel multiplexing number by the carry-out signal. At this time, the n-ary counter 30c is reset by a carry-out signal.
As a result, all the enable signals 1 to n of the data generation unit 17 provided for each channel are scanned by one n-ary counter 30a and the enable signal of which the enable signal is enabled by another n-ary counter 30c. The number is counted.
[0049]
That is, the enable number counter 30 detects the number of multiplexed transmission channels of the same carrier by counting the number of enable signals of the transmission data generating units 17-1 to 17-n.
Therefore, the count of the number of enable signals can be increased. Furthermore, the count operation of the number of enable signals is not required, and the speed of detecting the number of multiplexed signals can be increased.
[0050]
The configuration shown in FIG. 3 can also be used in other embodiments described later.
Subsequently, the coder unit 16 (see FIG. 2) encodes and codes the compensation parameter output from the compensation parameter generation unit 5 and the data to be transmitted output from the data generation unit 17. Data (coding data) is output. In addition, the coder unit 16 is configured to use a code for identifying the own station and other stations.
[0051]
More specifically, the coder unit 16 encodes the data to be transmitted to the base station 2 generated by the data generation unit 17 using the spreading code assigned to the terminal station 1. Yes. Thereby, a subscriber can be increased.
The coder unit 16 is provided as a codec unit together with a decoding unit (not shown) that processes coding data included in the RF signal transmitted from the base station 2.
[0052]
As a result, data to be transmitted is generated by the data generation unit 17, and the multiplexing number in the data generation unit 17 is detected by the multiplexing number detection unit 18. Then, the first control unit 24 reads the correction amount based on the multiplexing number from the first correction memory 19 and inputs the correction amount to the coder unit 16. Further, the coding unit 16 performs channel coding on the correction amount and the data to be transmitted output from the data generation unit 17, and the coding data is input to the modulation unit 25.
[0053]
Further, the modulation unit 25 primarily modulates the output from the coder unit 16 (spread signal to be transmitted, transmission multiplexed signal) using QPSK (Quadrature Phase Shift Keying) to generate an intermediate frequency signal (hereinafter referred to as IF signal [ Intermediate frequency signal])).
The first radio unit 12a converts the encoded data output from the coder unit 16 into a radio frequency and outputs an RF signal. The first radio unit 12a is realized by a high frequency circuit, for example, and receives an RF signal transmitted from the base station 2, converts the frequency, and outputs an IF signal. Hereinafter, detailed description of the flow of reception will be omitted.
[0054]
Furthermore, the antenna 11a transmits the RF signal output from the first wireless unit 12a as a radio wave to the transmission path. The antenna 11a also has a function of receiving an RF signal.
As a result, the coding data output from the coder unit 16 is primarily modulated by the modulation unit 25 and an IF signal is output. The IF signal is up-converted to an RF signal by the first radio unit 12a, level-amplified, and transmitted from the antenna 11a.
[0055]
The reception field strength compensation method of the present invention is performed in a wireless communication system 3 including a plurality of terminal stations 1 that transmit and receive an RF signal modulated by the CDMA system and a base station 2 that communicates with the terminal station 1. .
First, the terminal station 1 modulates data to be transmitted for each of one or a plurality of transmission channels (modulation step).
[0056]
Also, the terminal station 1 obtains a compensation parameter used for correcting the RSSI detection error on the receiving side due to the difference in the signal waveform with respect to the base station 2 (compensation parameter obtaining step). .
Then, the terminal station 1 encodes the data to be transmitted modulated in the modulation step and the compensation parameter acquired in the compensation parameter acquisition step, and transmits the encoded data (transmission step).
[0057]
As a result, the terminal station 1 and the base station 2 can be simplified, and the RSSI detection accuracy can be improved.
Here, the frame transmitted from the terminal station 1 to the base station 2 is as shown in FIG. 6, for example. FIG. 6 is a diagram showing a format example of a transmission frame. A frame 41 shown in FIG. 6 includes a synchronization signal (TFCI) unit 41a, data signal units (DATA1, DATA2) 41b, 41d, a pilot signal unit 41c, and a CRC ( (Cyclic Redundancy Check) signal unit 41e, and the coder unit 16 realizes the above function by inserting the above correction amount into the data signal unit 41b or 41d (or both).
[0058]
Then, the base station 2 receives an RF signal having a frame (see FIG. 6) transmitted from each of the plurality of terminal stations 1, and based on the spreading code assigned to each terminal station 1, each terminal station 1 is identified. Next, the reception flow of the base station 2 will be described with reference to FIG.
FIG. 4 is a block diagram of the receiving unit of the base station 2 according to the first embodiment of the present invention. The base station 2 shown in FIG. 4 is a fixed station, and the main part of the receiving unit of the base station 2 includes a main control unit 14b, an antenna 11b, a second radio unit 12b, and a baseband unit 36. Configured.
[0059]
The base station 2 has a transmission unit (transmission system) in addition to the reception unit. The transmission unit is not shown in the figure, but the transmission baseband signal output from the microphone, the audio processing circuit, and the audio processing circuit. A transmission baseband signal processing unit for processing the signal, a high-frequency circuit for wirelessly transmitting the IF signal output from the transmission baseband signal processing, and the like. Since these are well-known ones, detailed description thereof is omitted. And base station 2 (2a, 2b), such as other embodiment mentioned later, all has the transmission part. Hereinafter, with regard to the base station 2, the receiving unit will be mainly described.
[0060]
First, the main control unit 14b controls each unit included in the baseband unit 36, the second radio unit 12b, and the base station 2, and the antenna 11b transmits and receives RF signals.
Then, the second radio unit 12b receives an RF signal including a compensation parameter used for correcting an RSSI detection error on the receiving side due to a difference in signal waveform, and transmitted data, A reception main signal obtained by frequency-converting the RF signal and an RSSI voltage for the RF signal are output.
[0061]
The second radio unit 12b receives the RF signal that has been code-division multiplexed and outputs a received main signal and an RSSI voltage. The receiving unit of the second radio unit 12b will be further described in detail with reference to FIG.
FIG. 5 is a block diagram of the receiving unit of the second radio unit 12b according to the first embodiment of the present invention. 5 includes a bandpass filter (BPF) 32a and 32e, a low noise amplifier (LNA) 32b, a mixer (MIX) 32c and 32f, a local oscillator (Lo) 32d and 32g, and a lowpass filter (LPF). ) 32h, analog / digital (A / D) converters 32i and 32j, and a received electric field strength detector (RSSI detector) 32k.
[0062]
Here, the BPF 32a passes only a desired frequency component of the code multiplexed signal transmitted from the terminal station 1 received by the antenna 11b, and removes unnecessary components such as noise of the received signal. The LNA 32b amplifies the output of the BPF 32a to a desired level with low noise. The mixer 32c mixes the output of the LNA 32b and the output of the local oscillator 32d, thereby down-converting the RF signal into an IF signal. The BPF 32e has a desired frequency in the received signal after down-conversion. Only components are allowed to pass, and unnecessary components such as noise are removed.
[0063]
Further, the mixer 32f mixes the output of the BPF 32a and the output of the local oscillator 32d, thereby down-converting the IF signal into a baseband signal. The LPF 32h is a desired one of the IF signals after the down-conversion. Only the frequency component is passed, and unnecessary components such as noise are removed. The A / D converter 32i converts the output (analog signal) of the LPF 32h into a digital signal, and the baseband signal converted into the digital signal is a decoding unit included in the baseband unit 36 as a reception main signal. 20 (described later).
[0064]
The RSSI detector 32k (see FIG. 4) outputs an RSSI voltage using an amplifier having input and output voltages having desired characteristics. Specifically, a logarithmic amplifier (see FIG. 15). Is used. The received signal (IF signal) after down-conversion by the mixer 32f (see FIG. 5) is input, and the RSSI voltage is detected from the input signal. Thereby, the detection error due to the difference in the number of multiplexing caused by the input / output characteristics of the logarithmic amplifier of the RSSI detector 32k (see FIG. 13 and the like) is compensated. In addition, existing circuit components can be used, and the versatility of the components can be maintained.
[0065]
Further, the A / D converter 32j converts the analog RSSI voltage (output RSSI voltage value) detected by the RSSI detector 32k into a digital value, and the baseband unit 36 has the digital value. The data is output to the data demodulator 21 (described later).
Therefore, the second radio unit 12b outputs, to the baseband unit 36, the received main signal obtained by frequency-converting the RF signal as digital data, and outputs the RSSI voltage for the RF signal as digital data. ing.
[0066]
Next, in FIG. 4, the baseband unit 36 performs a logical operation necessary for the baseband signal output from the second radio unit 12 b in accordance with control by the main control unit 14 b, and includes a decoding unit (DECODER) 20. And a compensation parameter output unit 6, a correction unit (reception field strength correction unit) 23, and a data demodulation unit 21.
[0067]
The decoding unit 20 outputs a baseband signal resulting from the reception main signal output from the second radio unit 12b.
The compensation parameter output unit 6 outputs received field strength data and compensation parameters resulting from the RSSI voltage output from the second radio unit 12b, and includes an estimation memory (primary estimation memory) 22 and The first correction amount output unit (correction amount receiving unit) 26a and the memory control unit 37 are provided.
[0068]
Here, the estimation memory 22 holds received field strength data corresponding to the RSSI voltage output from the second radio unit 12b. The received electric field strength data is, for example, a digital value of voltage. The RSSI based on the reference wave and the input voltage are stored in advance in relation to each other. The reference wave is, for example, a spread CDMA wave, and a predetermined value is used as its effective value, and the RSSI is primarily estimated.
[0069]
The estimation memory 22 holds received field strength data in consideration of an offset value based on a reference wave having a predetermined characteristic for the RSSI voltage. This eliminates the need for special computation, corrects the RSSI detection error, and reduces the circuit scale.
The first correction amount output unit 26a outputs a correction amount corresponding to the multiplexing number indicating the number of transmission channels for the same carrier from the received main signal as a compensation parameter. The first correction amount output unit 26a is configured as an electric field strength correction amount extraction unit that extracts and outputs a correction amount from the received main signal.
[0070]
Further, the memory control unit 37 reads the received electric field strength data from the estimation memory 22 based on the RSSI voltage and inputs the received field strength data to the correction unit 23.
Thereby, the compensation parameter output unit 6 gives the correction unit 23 the received field strength data primarily estimated by the estimation memory 22 and the correction amount output from the first correction amount output unit 26a, respectively. , To enter. This also increases the RSSI detection accuracy.
[0071]
Next, the correction unit 23 outputs corrected reception field strength data based on the reception field strength data output from the compensation parameter output unit 6 and the compensation parameters. Further, the data demodulator 21 outputs demodulated data based on the baseband signal output from the decoder 20 and the corrected received electric field strength data output from the corrector 23.
[0072]
As a result, the received field strength compensation method of the present invention starts with the compensation for base station 2 used for correcting the RSSI detection error on the receiving side (base station 2) due to the difference in signal waveform. An RF signal having parameters is received (receiving step). Next, the base station 2 detects the RSSI of the RF signal received in the reception step (detection step).
[0073]
Then, the base station 2 corrects the RSSI detection error based on the compensation parameter included in the RF signal received in the reception step and the RSSI detected in the detection step (correction step).
Therefore, the RSSI detection error can be improved regardless of the multiplexing number of the terminal station 1 and the modulation method.
[0074]
More specifically, in the reception flow in the base station 2, the RF signal from the transmission path is received by the antenna 11b, the second radio unit 12b converts the frequency of the RF signal into a baseband signal, and the baseband unit 36 Performs logic processing necessary for reception according to the control of the main control unit 14b.
Also, the RSSI detection unit 32k of the second radio unit 12b converts the RSSI into an RSSI voltage using a logarithmic amplifier, and inputs the RSSI voltage to each of the data demodulation unit 21 and the decoding unit 20. Then, the first correction amount output unit 26a receives the correction amount corresponding to the multiplexing number from the received main signal, and inputs the correction amount to the correction unit 23 as a compensation parameter. That is, the RSSI voltage and the received data are separated by the decoding unit 20.
[0075]
Further, the estimation memory 22 performs primary estimation of the RSSI based on the RSSI voltage output from the second radio unit 12b, and the memory control unit 37 reads the received electric field strength data corresponding to the RSSI voltage, and the received electric field strength. Data is input to the correction unit 23. And the correction | amendment part 23 correct | amends RSSI based on each of the RSSI estimated primarily, and a correction amount.
[0076]
Thus, as the information for each sector (area obtained by dividing the radio communication zone) from the terminal station 1, the number of transmission channels multiplexed in the terminal station 1 is notified to the base station 2, and the base station 2 logs The output voltage of the amplifier is corrected.
The wireless communication system 3 (see FIG. 1) of the present invention includes a plurality of terminal stations 1 that transmit and receive code division multiplexed RF signals and a base station 2 that communicates with the terminal stations 1. Then, the terminal station 1 generates a data to be transmitted including control data and information data and outputs the data generation unit 17 for correcting a detection error of RSSI on the reception side due to a difference in signal waveform. The compensation parameter generation unit 5 that outputs the compensation parameters used in the process, the compensation parameter output from the compensation parameter generation unit 5 and the data to be transmitted output from the data generation unit 17 are encoded and encoded. A coder unit 16 that outputs encoded data, and a first radio unit 12a that converts encoded data output from the coder unit 16 into a radio frequency and outputs an RF signal.
[0077]
Further, the base station 2 receives the RF signal, and outputs the received main signal obtained by frequency-converting the RF signal and the RSSI voltage for the RF signal, and the second radio unit 12b outputs the received radio signal. A decoding unit 20 that outputs a baseband signal resulting from the received main signal, and a compensation parameter output unit 6 that outputs received field strength data and compensation parameters resulting from the RSSI voltage output from the second radio unit 12b. A correction unit 23 that outputs corrected reception field strength data based on the reception field strength data output from the compensation parameter output unit 6 and the compensation parameter; a baseband signal output from the decoding unit 20; A data demodulating unit 21 that outputs demodulated data based on the corrected received electric field strength data output from the unit 23 is provided.
[0078]
A method of correcting the RSSI of the system 3 configured as described above will be described with reference to FIGS.
First, data to be transmitted is generated for each transmission channel in the data generation unit 17 of the terminal station 1 in FIG. The data to be transmitted is spread in the coder unit 16 using a spreading code assigned to each terminal station 1 in advance, and the code-multiplexed RF signal is transmitted through the modulation unit 25 to the antenna 11a. Sent from
[0079]
In the terminal station 1, the enable number counter 30 of the multiplexing number detection unit 18 counts the number of enable signals of the transmission data generation units 17-1 to 17-n, and the multiplexing number detection unit 18 transmits the channel being transmitted. Is monitored, and the first control unit 24 is notified of the multiplexing number. Then, the first control unit 24 reads out correction amount data corresponding to the number of multiplexed transmission channels stored in advance from the first correction memory 19, and the correction amount data together with other data to be transmitted together with channel coding. Thus, the coder unit 16 is controlled.
[0080]
Further, the main control unit 14a controls the logical processing in the baseband unit 15 and the first radio unit 12a, respectively, and transmits an RF signal on which correction amount data is superimposed.
On the other hand, the RSSI detector 32k of the base station 2 converts the RSSI into an RSSI voltage, A / D converts the RSSI voltage, and notifies the main controller 14b. The main control unit 14b primarily estimates the RSSI corresponding to the RSSI voltage from the estimation memory 22, and separates the transmission data framed in the decoding unit 20.
[0081]
The main control unit 14b separates the correction amount based on the multiplexing number, and the correction unit 23 corrects the RSSI based on the separated correction amount.
Thus, since the terminal station 1 transmits the correction amount to the base station 2 and the base station 2 corrects the RSSI detection error using the correction amount, the RSSI detection accuracy in the base station 2 is greatly increased. To improve.
[0082]
In addition, since the transmission powers of the terminal station 1 and the base station 2 are both determined to be appropriate values in this way, the power consumption of the terminal station 1 and the base station 2 can be reduced, and communication due to near / far problems A reduction in quality can be suppressed, and the number of terminal stations 1 that can be accommodated can be increased by improving the frequency utilization efficiency.
By the way, the multiplex number detection unit 18 can use other forms. As an example, two types (hereinafter referred to as a second form and a third form) are referred to FIG. 7 and FIG. I will explain.
[0083]
FIG. 7 is a second block diagram of the multiplex number detection unit and the data generation unit according to the first embodiment of the present invention. The multiplex number detector 18a shown in FIG. 7 outputs an enable number for each channel group obtained by dividing a plurality of transmission channels. The multiple number detection unit 18a includes a first control unit 24, enable number counters 33a to 33c, an adder (Σ) 34, and a flip-flop (FF) 30d. Further, in FIG. 7, those having the same reference numerals as those described above are the same or similar, and redundant description is omitted.
[0084]
Here, each of the enable number counters 33a to 33c counts the enable number for each channel group for the same carrier. That is, the number n of transmission channels is divided into, for example, every two channels, and transmission data generation units 17-1 to 17-n corresponding to the divided transmission channels are provided. Then, for each of these groups, the enable number counters 33a to 33c count the enable number.
[0085]
Further, the adder 34 adds outputs (count results) of the enable number counters 33a to 33c, and the flip-flop 30d temporarily holds the output of the adder 34.
As a result, in the multiplexing number detection unit 18a, the number of enables output from the first control unit 24 is counted for each group by each of the enable number counters 33a to 33c. Can be completed in a short time.
[0086]
Also, this enables the enable signal to be divided into a plurality of blocks and counted in parallel, and finally the counter output is added, so that the operation speed is increased. The multiplex number detection unit 18a shown in FIG. 7 can also be used in other embodiments described later.
Next, a 3rd form is demonstrated.
[0087]
FIG. 8 is a third block diagram of the multiplex number detection unit and the data generation unit according to the first embodiment of the present invention. The multiplex number detection unit 18b shown in FIG. 8 is provided with a multiplex number memory (address ROM) 35 on the input side of the output flip-flop 30d. Also in FIG. 8, those having the same reference numerals as those described above are the same or similar, and redundant description is omitted.
[0088]
The multiplex number memory 35 holds a multiplex number based on an address that is output from the data generation unit 17 and that is composed of a combination of enable signals indicating ON / OFF of transmission channels for the same carrier.
Then, each of the enable signals output from the first control unit 24 is held as, for example, 1-bit information in the flip-flops 31a to 31d, and n bits of the flip-flops 31a to 31d are read in the multiplex number memory 35. The multiplex number stored in advance is read out from the address area corresponding to the read address signal, which is input as an address signal.
[0089]
For example, when n = 3, the multiplex number “1” is assigned to each of the addresses “001”, “010”, and “100” of the multiplex number memory 35, and the multiplex numbers “011” and “110” are assigned to the respective regions. In the areas of the number “2” and the address “111”, the multiplex number “3” is stored in advance. That is, the number of “1” in the n-bit address represents the multiplex number.
[0090]
For example, when the enable signal is supplied to only two types of transmission data generation units 17-1 and 17-3, only the outputs of the flip-flops 31a and 31c become "1", and the read address signal is "101". ″ Accordingly, the multiplex number “2” stored at the address “101” is read from the multiplex number memory 35 and output as the multiplex number.
[0091]
Note that the configuration shown in FIG. 8 is applied to the enable counters 33a to 33c for each group shown in FIG. Further, the multiplexing number detection unit 18b shown in FIG. 8 can be used in other embodiments described later.
In this way, the n enable signals to each of the transmission data generation units 17-1 to 17-n directly indicate the read address of the multiplex number memory 35, so that it is not necessary to count the enable signal. Detection can be completed in a short period of time.
[0092]
(A1) Description of Modification of First Embodiment of the Present Invention
In the modification of the first embodiment, the terminal station 1a transmits the multiplex number as the compensation parameter to the base station 2a. Further, the wireless communication system 3a in the modification is the same as the system 3 shown in FIG.
FIG. 9 is a block diagram of a transmission unit of the terminal station 1a according to the modification of the first embodiment of the present invention. The terminal station 1a shown in FIG. 9 is a mobile phone or the like using a code division multiple access communication system, and includes a main control unit 14a, a baseband unit 15a, a first radio unit 12a, and an antenna 11a. Configured.
[0093]
The baseband unit 15a performs a logical operation necessary for generating a signal (information data and control data) to be transmitted according to control by the main control unit 14a and inputting the signal to the first radio unit 12a. The data generation unit 17, the compensation parameter generation unit 5 a, the coder unit 16, and the modulation unit 25 are provided.
Here, the compensation parameter generation unit 5a includes a multiplex number detection unit 18 that detects a multiplex number indicating the number of transmission channels for the same carrier and outputs the multiplex number as a compensation parameter.
[0094]
Further, the first control unit 24 inputs the compensation parameters in the compensation parameter generation unit 5 a to the coder unit 16. Specifically, the first control unit 24 inputs the multiplex number in the multiplex number detection unit 18 to the coder unit 16. Thereby, the correction amount can be controlled according to the communication status.
In addition, since what has the same code | symbol as what was mentioned above has the same thing or a similar function, the further description is abbreviate | omitted.
[0095]
As a result, the coder unit 16 channel-codes the multiplex number output from the multiplex number detection unit 18 and the data to be transmitted output from the data generation unit 17 to output coding data, and the first radio unit 12a. Is transmitted as an RF signal.
Next, FIG. 10 is a block diagram of the receiving unit of the base station 2a according to a modification of the first embodiment of the present invention. The main part of the receiving unit in the base station 2a shown in FIG. 10 includes an antenna 11b, a second radio unit 12b, a baseband unit 36a, and a main control unit 14b. In addition, since what has the same code | symbol as what was mentioned above has the same thing or a similar function, the further description is abbreviate | omitted.
[0096]
Here, the baseband unit 36a performs a logical operation necessary for the baseband signal output from the second radio unit 12b in accordance with control by the main control unit 14b. The baseband unit 36a includes a decoding unit 20 and a compensation parameter output unit. 6a, a correction unit (received electric field strength correction unit) 23, and a data demodulation unit 21.
The compensation parameter output unit 6a outputs received field strength data and compensation parameters caused by the RSSI voltage output from the second radio unit 12b. The compensation parameter output unit 6a outputs an estimation memory 22, a multiplex number receiving unit ( A multiple number detection unit (displayed as reception) 26 b, a memory control unit 37, and a second correction amount output unit (second correction memory) 38.
[0097]
The estimation memory 22 holds reception field strength data corresponding to the RSSI voltage output from the second radio unit 12b. The multiplexing number receiving unit 26b outputs a multiplexing number indicating the number of transmission channels for the same carrier from the received main signal.
Further, the second correction amount output unit 38 outputs a correction amount corresponding to the multiplex number output from the multiplex number receiving unit 26b as a compensation parameter. The second correction amount output unit 38 includes a second correction memory 38a that holds a correction amount corresponding to the number of multiplexing.
[0098]
The second correction memory unit 38a and the estimation memory 22 may be shared, and in this way, the terminal station 1a can be downsized.
As a result, the multiplex number is output from the received main signal in the multiplex number receiving unit 26b, and the multiplex number output from the multiplex number receiving unit 26b is output in the second correction amount output unit 38 (second correction memory 38a). The corresponding correction amount is input to the correction unit 23 as a compensation parameter.
[0099]
Thereby, the compensation parameter output unit 6a gives the correction unit 23 the received electric field strength data primarily estimated by the estimation memory 22 and the multiplex number output from the second correction amount output unit 38. Each is converted into a correction amount and input.
With such a configuration, any one of the terminal stations 1a code-multiplexes and transmits an RF signal including the multiplexing number and the transmitted data to the base station 2a. Then, the RF signal is frequency-converted into a baseband signal by the second radio unit 12b in the base station 2a, and logic processing necessary for reception is performed by the baseband unit 36a under the control of the main control unit 14b.
[0100]
Further, the multiplexing number is read from the decoding unit 20 by the multiplexing number receiving unit 26b, and the read multiplexing number is input to the second correction memory 38a.
On the other hand, the RSSI voltage output from the RSSI detection unit 32k of the second radio unit 12b is first estimated from the estimation memory 22 by the memory control unit 37, and the retained data is input to the correction unit 23. The correction unit 23 corrects the RSSI by using the correction tatami mat read from the decoding unit 20.
[0101]
As a result, the RSSI detection error caused by the difference in the number of multiplexed reception main signals included in the logarithmic amplifier of the RSSI detector 23 is compensated.
As described above, it is possible to improve the RSSI detection accuracy in the base station 2a while saving power and simplifying the terminal station 1a.
(B) Description of the second embodiment of the present invention
The radio communication system 3b (see FIG. 1) in the second embodiment uses a CDMA system and corresponds to a plurality of modulation systems. An example of the system 3b is a mobile phone service, and a base station 2b that supports a plurality of types of modulation schemes, and a modulation scheme that is supported by the base station 2b in the wireless communication zone of the base station 2b. The terminal station 1b communicates with the base station 2b using the desired modulation method.
[0102]
Here, the base station 2b receives the compensation parameters in addition to the information data and control data transmitted from the terminal station 1b, and corrects the RSSI based on the compensation parameters. The base station 2b is accommodated in an exchange 4a having an exchange function and can exchange data with the network 4b.
Further, the terminal station 1b transmits the modulation parameter to the base station 2b together with data to be transmitted including information data such as voice or file data and control data. The function of the terminal station 1b is realized by, for example, a software defined radio.
[0103]
FIG. 11 is a block diagram of a transmission unit of the terminal station 1b according to the second embodiment of the present invention. A terminal station 1b shown in FIG. 11 is, for example, a mobile phone, and includes an antenna 11a, a first radio unit 12a, a baseband unit 36b, and a main control unit 14a.
Here, the baseband unit 36b performs a logical operation necessary for generating a signal to be transmitted in accordance with control by the main control unit 14a and inputting the signal to the first radio unit 12a. The compensation parameter generation unit 5b, the coder unit 16, and the modulation unit 25 are provided.
[0104]
Here, the compensation parameter generation unit 5b outputs an intercept factor corresponding to the modulation scheme and a correction amount corresponding to the intercept factor, and includes an intercept factor determination unit (determined and displayed) 40a. And a memory 40b. The intercept factor is a statistical parameter when designing the system specification, and specifically corresponds to a modulation method.
[0105]
The intercept factor determining unit 40a determines an intercept factor corresponding to the modulation method, and a read address of the memory 40b corresponding to the determined intercept factor is generated.
The memory 40b holds a correction amount corresponding to the intercept factor determined by the intercept factor determination unit 40a as a compensation parameter. For each difference in intercept factor (difference in modulation method), the correction amount is held as information in a table format. Then, the correction amount is read out by the read address output from the intercept factor determination unit 40 a and is input to the coder unit 16.
[0106]
That is, the compensation parameter generator 5b uses the modulation method as a compensation parameter necessary for correcting an RSSI detection error that may occur in the terminal station 1b due to a difference in signal waveform due to the modulation method of the base station 2b. It generates information about. This information means a correction amount according to the modulation method (intercept factor). Therefore, it is possible to support the multimode compatible terminal station 1b.
[0107]
In addition, since the thing which has the same code | symbol as what was mentioned above other than these has the same thing or the same function, the overlapping description is abbreviate | omitted.
Thereby, in the terminal station 1b, the intercept factor according to the modulation scheme or the correction amount according to the intercept factor is superimposed on the data to be transmitted, and the data is transmitted.
[0108]
On the other hand, the base station 2b includes a correction table memory that outputs a correction amount according to the modulation method, and the detected RSSI is corrected by the correction amount according to the received intercept factor.
FIG. 12 is a block diagram of the transmission unit of the base station 2b according to the second embodiment of the present invention. The main part of the transmission unit in the base station 2b shown in FIG. 12 includes an antenna 11b, a second radio unit 12b, a baseband unit 36b, and a main control unit 14b.
[0109]
Here, the baseband unit 36b performs a logical operation necessary for the baseband signal output from the second radio unit 12b in accordance with control by the main control unit 14b. The baseband unit 36b includes a decoding unit 20 and a compensation parameter output unit. 6b, a correction unit (received electric field intensity correction unit) 23, and a data demodulation unit 21.
The compensation parameter output unit 6b includes an estimation memory 22, a modulation parameter output unit (displayed as output) 21c, and a third correction amount output unit 39 (third correction memory 39a). It is configured. Here, the modulation parameter output unit 21c outputs a modulation parameter representing a modulation method from the received main signal.
[0110]
The third correction amount output unit 39 outputs a correction amount corresponding to the modulation parameter output from the modulation parameter output unit 21c as a compensation parameter. The third correction amount output unit 39 includes a third correction memory 39a that holds a correction amount corresponding to the modulation parameter.
Therefore, it is possible to improve the RSSI detection accuracy in the base station 2b while simplifying the terminal station 1b and saving power.
[0111]
In addition, since the thing which has the same code | symbol as what was mentioned above other than these has the same thing or the same function, the overlapping description is abbreviate | omitted.
With such a configuration, the terminal station 1b first communicates with the base station 2b using the first modulation scheme, and then changes to the second modulation scheme different from the first modulation scheme and changes to the base station 2b. Communicate with and send data to be sent.
[0112]
In addition, the terminal station 1b notifies the base station 2b of a correction amount according to the difference in modulation scheme (intercept factor), and the base station 2b corrects the RSSI detection error. The base station 2b can correct the error even if an RSSI detection error occurs due to the difference in the modulation method used.
Furthermore, since the terminal station 1b calculates a correction amount from the intercept factor and notifies only the correction amount to the base station 2b, the base station 2b can be simplified and downsized in this case as well.
[0113]
Therefore, even if the terminal station 1b is a software defined radio, the RSSI detection accuracy can be greatly improved. For example, the presence / absence of radio waves transmitted by an illegal radio can be estimated with high accuracy based on the RSSI. Is possible. As a result, for example, it is possible to control illegal wireless devices with extremely high performance.
(B1) Description of Modification of Second Embodiment
In the modification of the second embodiment, the correction memory (the first correction memory 19, the second correction memory 38a, and the third correction memory) that outputs a correction amount corresponding to the transmission channel multiplexing number received by the base station 2 (2a, 2b). Instead of the correction memory 39a and the like, correction is performed by calculation using a calculation formula. That is, RSSI is obtained by a predetermined calculation. Also in this modification, the system 3b (see FIG. 1) using the CDMA system is applied, and the terminal station 1b and the base station 2b are used.
[0114]
Here, the memory control unit 37 shown in FIG. 12 outputs the received electric field strength data by a predetermined calculation based on RSSI.
It is also possible to use the terminal stations 1 and 1a (see FIGS. 2 and 10).
With such a configuration, first, the RSSI detection unit 32k converts the RSSI into an RSSI voltage, and the RSSI voltage is A / D converted and then notified to the main control unit 14b. The main control unit 14b primarily estimates the received electric field strength (RSSI # 1) according to the RSSI voltage from the estimation memory 22, and the decoding unit 20 determines the transmission channel multiplexing number n in the same carrier transmitted from the terminal station 1b. To be separated. Further, the main control unit 14b obtains the received electric field strength (RSSI # 2) to be obtained by the following equation (3) using (RSSI # 2) estimated by the estimation memory 22.
[0115]
RSSI # 2 = RSSI # 1 + (A * n + B) (3)
Here, n represents the multiplex number received by the multiplex number receiving unit 26b, A and B are both coefficients, and * represents multiplication.
In this way, the RSSI can be corrected, the correction amount is obtained by calculation from the number of multiplexed transmission channels, and the RSSI detected due to the difference in the number of multiplexed transmission channels is corrected by correcting the RSSI by the correction amount. Errors are compensated.
[0116]
Accordingly, a memory for estimating the RSSI according to the output voltage of the RSSI detection unit 32k becomes unnecessary, and the correction amount can be obtained with higher accuracy than in the case of using the memory, so that the base station 2b can be downsized. However, it is possible to compensate for the RSSI detection error caused by the difference in the number of multiplexed transmission channels with high accuracy.
(C) Other
The present invention is not limited to the above-described embodiments and modifications thereof, and various modifications can be made without departing from the spirit of the present invention.
[0117]
As described above, the wireless communication system 3 (3a, 3b) uses the CDMA system, but the present invention is also applicable to, for example, GSM (Global System for Mobile Communications). As a spreading method, not only direct spreading but also a method of switching the transmission frequency in the IF signal band can be used.
Further, regarding the modulation circuit, the baseband signal output from the data generation unit 17 is converted into an IF signal by the modulation unit 25 and is up-converted to an RF signal by the first radio unit 12a. You may make it up-convert directly in the part 17. FIG. Similarly, when demodulating, the baseband signal may be obtained directly by down-converting from the RF signal.
[0118]
The received electric field strength data input to the received electric field strength correction unit 23 can use a pointer or the like in addition to a digital voltage value. For example, another memory is provided in the data demodulator 21 and the correction unit 23 so that a pointer to the memory is input to the correction unit 23. Even if such a modified embodiment is used, the superiority of the present invention is not impaired.
[0119]
The first correction amount output unit 26a is configured as an electric field intensity correction amount extraction unit that extracts and outputs a correction amount from the received main signal, and can extract an electric field intensity correction amount from another signal, for example. .
In addition, the enable number counter 30 shown in FIG. 3 is not limited to the above-described configuration, and uses a logic circuit that combines an n-ary counter 30a and a decoder 30b, or combines an n-ary counter 30c and a flip-flop 30d. Is also possible.
[0120]
Furthermore, in each embodiment and its modification, it can transmit multiple times from the terminal station 1 (1a, 1b) to the base station 2 (2a, 2b). For example, when the base station 2 (2a, 2b) broadcasts information related to the modulation scheme, the broadcast is performed every time the modulation scheme is changed. In addition, the correction amount and the multiplexing number corresponding to the transmission channel multiplexing number are frequently changed, so that they are notified at regular intervals using a timer or the like.
[0121]
Further, the systems described in the embodiments can be implemented in combination. For example, the terminal station 1 (1a, 1b) has a multi-mode function that supports the TACS method and the CDMA method, and the RSSI generated due to the difference in signal waveform generated between the TACS method and the CDMA method is detected. It is possible to compensate for the error and the RSSI detection error caused by the difference in the number of multiplexed transmission channels in the CDMA system.
[0122]
Furthermore, in the frame shown in FIG. 6, the position for inserting the compensation parameter can be variously changed.
In FIG. 7, the data generation units 17a, 17b, and 17c are all the same as the data generation unit 17, and are respectively the transmission data generation units 17-1 and 17-2 and the transmission data generation unit 17-. 3 and 17-4 and transmission data generation units 17- (n-1) and 17-n.
[0123]
(D) Appendix
(Supplementary Note 1) A data generation unit that generates and outputs data to be transmitted including control data and information data;
A compensation parameter generating unit that outputs a compensation parameter used for correcting a detection error of the reception electric field intensity on the reception side due to a difference in signal waveform;
A coder that encodes the compensation parameter output from the compensation parameter generator and the data to be transmitted output from the data generator and outputs encoded data;
A terminal station for a radio communication system, comprising: a first radio unit that converts the encoded data output from the coder unit into a radio frequency and outputs a radio signal.
[0124]
(Appendix 2) The coder section
The terminal station for a wireless communication system according to appendix 1, wherein the terminal station is configured to encode using a code for identifying the own station and another station.
(Supplementary Note 3) The compensation parameter generation unit
A multiplex number detection unit that detects and outputs a multiplex number indicating the number of transmission channels for the same carrier;
The wireless communication according to claim 2, further comprising: a first correction memory that holds, as the compensation parameter, an electric field intensity correction amount corresponding to the multiplex number output from the multiplex number detection unit. Terminal station for the system.
[0125]
(Supplementary Note 4) The multiple number detection unit
A plurality of holding units for holding the enable signal;
A first counter that outputs a channel number corresponding to the enable signal;
An address output unit for outputting addresses of the plurality of holding units corresponding to the channel numbers output from the first counter;
The terminal station for a wireless communication system according to appendix 3, characterized by comprising a second counter for counting the number of the enable signals held in each of the plurality of holding units.
[0126]
(Supplementary Note 5) The multiple number detection unit
The terminal station for a wireless communication system according to appendix 4, wherein the terminal is configured to output an enable number for each channel group obtained by dividing a plurality of transmission channels.
(Supplementary Note 6) The multiple number detection unit
A multiplex number memory that holds the multiplex number based on an address that is output from the data generation unit and represents a combination of enable signals indicating ON / OFF of a transmission channel for the same carrier is provided. A terminal station for a wireless communication system according to appendix 2.
[0127]
(Supplementary note 7) The compensation parameter generation unit
3. A radio communication system for a wireless communication system according to appendix 2, characterized by comprising a multiplex number detection unit for detecting a multiplex number indicating the number of transmission channels for the same carrier and outputting the multiplex number as the compensation parameter. Terminal station.
(Supplementary Note 8) As described in any one of Supplementary notes 1 to 7, wherein the compensation parameter generation unit is configured to include a first control unit that inputs the compensation parameter to the coder unit. A terminal station for a wireless communication system.
[0128]
(Supplementary Note 9) The compensation parameter generation unit
An intercept factor determining unit that determines an intercept factor according to a modulation method;
A terminal station for a wireless communication system, comprising: a memory that holds, as the compensation parameter, an electric field intensity correction amount corresponding to the intercept factor determined by the intercept factor determination unit.
[0129]
(Supplementary Note 10) A radio signal including a compensation parameter used for correcting a detection error of a received electric field strength on the receiving side due to a difference in signal waveform and transmitted data is received, and the radio signal is received. A second radio unit that outputs at least one of a received main signal obtained by frequency-converting the received signal and a received electric field strength voltage for the radio signal;
A decoding unit for outputting a baseband signal resulting from the received main signal output from the second radio unit;
A compensation parameter output unit for outputting received field strength data resulting from the received field strength voltage output from the second radio unit and the compensation parameter;
A correction unit that outputs corrected reception field strength data based on the reception field strength data output from the compensation parameter output unit and the compensation parameter;
The baseband signal output from the decoding unit and the data demodulating unit that outputs demodulated data based on the corrected received electric field strength data output from the correcting unit, A base station for a wireless communication system.
[0130]
(Supplementary Note 11) The second radio unit is
11. The radio communication system according to appendix 10, wherein the radio communication system is configured to receive a code division multiplexed radio signal and output at least one of the received main signal and the received field strength voltage. Base station.
(Supplementary Note 12) The compensation parameter output unit
An estimation memory for holding received field strength data corresponding to the received field strength voltage output from the second wireless unit;
A first correction amount output unit configured to output, as the compensation parameter, an electric field intensity correction amount corresponding to a multiplexing number indicating the number of transmission channels for the same carrier from the received main signal; , A base station for a wireless communication system according to appendix 11.
[0131]
(Supplementary Note 13) The first correction amount output unit includes:
13. The base station for a wireless communication system according to appendix 12, wherein the base station is configured as an electric field intensity correction amount extraction unit that extracts and outputs the electric field intensity correction amount from the received main signal.
(Supplementary Note 14) The compensation parameter output unit
An estimation memory for holding received field strength data corresponding to the received field strength voltage output from the second wireless unit;
A multiplex number receiver for outputting a multiplex number indicating the number of transmission channels for the same carrier from the received main signal;
The additional correction amount output unit configured to output a field intensity correction amount corresponding to the multiplex number output from the multiplex number receiving unit as the compensation parameter. A base station for a wireless communication system.
[0132]
(Supplementary Note 15) The second correction amount output unit
15. The base station for a wireless communication system according to appendix 14, wherein the base station is configured by a second correction memory that holds the electric field intensity correction amount corresponding to the multiplexing number.
(Supplementary Note 16) The compensation parameter output unit
An estimation memory for holding received field strength data corresponding to the received field strength voltage output from the second wireless unit;
A modulation parameter output unit for outputting a modulation parameter representing a modulation method from the received main signal;
The supplementary note 11 is characterized by comprising a third correction amount output unit that outputs, as the compensation parameter, an electric field intensity correction amount corresponding to the modulation parameter output from the modulation parameter output unit. A base station for a wireless communication system.
[0133]
(Supplementary Note 17) The third correction amount output unit
18. The base station for a wireless communication system according to appendix 16, wherein the base station is configured by a third correction memory that holds the electric field intensity correction amount corresponding to the modulation parameter.
(Supplementary Note 18) The compensation parameter output unit
Any one of Supplementary notes 10 to 17, further comprising a memory control unit that reads out the received field strength data from the estimation memory based on the received field strength voltage and inputs the data to the correction unit. A base station for the wireless communication system described in 1.
[0134]
(Supplementary note 19) The memory control unit
Item 19. The base station for a wireless communication system according to appendix 18, wherein the received field strength data is output by a predetermined calculation based on the received field strength.
(Supplementary Note 20) The second radio unit is
The wireless communication system according to any one of appendix 10 to appendix 19, wherein the received electric field strength voltage is output using an amplifier having input and output voltages having desired characteristics. Base station.
[0135]
(Supplementary note 21) The estimated memory is
Any one of appendix 10 to appendix 20, wherein the received electric field strength voltage is configured to hold the received electric field strength data in consideration of an offset value based on a reference wave having a predetermined characteristic. A base station for the wireless communication system described in 1.
(Supplementary note 22) a plurality of terminal stations that transmit and receive a radio signal modulated by a desired radio communication method;
A base station that communicates with the terminal station;
The terminal station
A data generation unit that generates and outputs data to be transmitted including control data and information data;
A compensation parameter generating unit that outputs a compensation parameter used for correcting a detection error of the reception electric field intensity on the reception side due to a difference in signal waveform;
A coder that encodes the compensation parameter output from the compensation parameter generator and the data to be transmitted output from the data generator and outputs encoded data;
A first radio unit that converts the encoded data output from the coder unit into a radio frequency and outputs the radio signal;
further,
The base station
A second radio unit that receives the radio signal and outputs at least one of a reception main signal obtained by frequency-converting the radio signal and a received electric field strength voltage for the radio signal;
A decoding unit for outputting a baseband signal resulting from the received main signal output from the second radio unit;
A compensation parameter output unit for outputting received field strength data resulting from the received field strength voltage output from the second radio unit and the compensation parameter;
A correction unit that outputs corrected reception field strength data based on the reception field strength data output from the compensation parameter output unit and the compensation parameter;
The baseband signal output from the decoding unit and the data demodulating unit that outputs demodulated data based on the corrected received electric field strength data output from the correcting unit, Wireless communication system.
[0136]
(Supplementary note 23) In a wireless communication system comprising a plurality of terminal stations that transmit and receive a radio signal modulated by a desired wireless communication system, and a base station that communicates with the terminal station,
A modulation step in which the terminal station modulates data to be transmitted for each of one or more transmission channels;
A compensation parameter acquisition step in which the terminal station acquires, for the base station, a compensation parameter used for correcting a detection error of a reception electric field strength on the reception side due to a difference in signal waveform;
A transmission step in which the terminal station encodes the data to be transmitted modulated in the modulation step and the compensation parameter acquired in the compensation parameter acquisition step and transmits encoded data. A received electric field strength compensation method, comprising:
[0137]
(Supplementary Note 24) In a wireless communication system comprising a plurality of terminal stations that transmit and receive a radio signal modulated by a desired wireless communication system, and a base station that communicates with the terminal station,
A receiving step in which the base station receives a radio signal having a compensation parameter used for correcting a detection error of a received electric field strength on the receiving side due to a difference in signal waveform;
A detecting step in which the base station detects a received electric field strength of the radio signal received in the receiving step;
The base station corrects the detection error of the reception field strength based on the compensation parameter included in the radio signal received in the reception step and the reception field strength detected in the detection step. And a correction step for correcting the received electric field strength.
[0138]
【The invention's effect】
  As detailed above,ClearlyAccording to this, the following effects or advantages can be obtained.
[0139]
  (1)TimesSince the increase in the road scale and the detection of the received electric field strength error are each removed, the correction amount as the compensation parameter, the multiplexing number, and the modulation method itself are reported from the terminal station to the base station. It becomes possible to correct the received electric field strength detected in.
[0140]
  (2)ExampleFor example, when the CDMA system is used, the transmission power level self-determined from the received electric field strength becomes a more appropriate value, so that it is possible to prevent the communication quality from deteriorating due to the perspective problem.
[0141]
  (3)endThe power consumption of the terminal station and the base station can be reduced, the deterioration of communication quality due to near / far problems can be suppressed, and the number of terminal stations that can be accommodated can be increased by improving the frequency utilization efficiency..
[0142]
  (4)endThe end station and base station can be simplified, and the detection accuracy of the received electric field strength can be improved..
[0143]
  (5)endThe detection error of the received electric field strength can be improved regardless of the number of end stations and the modulation method..
[0144]
(6) The coder unit may be configured to encode using a code for identifying the local station and the other station. In this way, the received electric field strength can be accurately detected, and the subscriber is Can be increased.
(7) A compensation parameter generation unit detects a multiplex number and outputs a multiplex number detection unit, and a first correction memory that holds a correction amount corresponding to the multiplex number output from the multiplex number detection unit as a compensation parameter In this way, it is possible to detect information on the multiplex number with a simple configuration.
[0145]
(8) The multiplexing number detection unit may be configured to include a plurality of holding units, a first counter, an address output unit, and a second counter. In this way, the circuit operation can be speeded up. .
(9) The multiplex number detection unit may be configured to output the enable number for each channel group. In this way, for example, the operation of counting the number of enable signals is not required, and the multiplex number detection is speeded up. Can be planned.
[0146]
(10) The multiplex number detection unit may be configured to include a multiplex number memory that holds a multiplex number based on an address composed of a combination of enable signals, and the compensation parameter generation unit detects the multiplex number and performs multiplexing. A multiplex number detection unit that outputs the number as a compensation parameter may be provided. In this way, detection of the multiplex number can be completed in a short period of time.
[0147]
(11) The terminal station may be configured to include a first control unit that inputs the compensation parameter in the compensation parameter generation unit to the coder unit. In this way, the correction amount is set according to the communication situation. Can be controlled.
(12) The compensation parameter generation unit may be configured to include an intercept factor determination unit and a memory, and in this way, a multimode compatible terminal station can be supported.
[0148]
(13) The second radio unit may be configured to receive a code division multiplexed radio signal and output a received main signal and a received electric field strength voltage. In this way, the circuit scale can be reduced. Can be
(14) The compensation parameter output unit may include an estimation memory and a first correction amount output unit, and the first correction amount output unit extracts a correction amount from the received main signal. In this way, a special calculation at the base station can be eliminated and a detection error of the received electric field strength can be corrected.
[0149]
(15) The compensation parameter output unit may include an estimation memory, a multiplex number receiving unit, and a second correction amount output unit, and the second correction amount output unit corresponds to the multiplex number. The second correction memory that holds the amount of correction to be performed may be used, and in this way, the terminal station can be downsized.
(16) The compensation parameter output unit may include an estimation memory, a modulation parameter output unit, and a third correction amount output unit, and the third correction amount output unit corresponds to the modulation parameter. In this way, the terminal station can be simplified and the power can be saved while improving the detection accuracy of the received electric field strength at the base station. Can do.
[0150]
(17) The compensation parameter output unit may include a memory control unit that reads out received field strength data from the estimation memory based on the received field strength voltage and inputs the data to the correction unit. However, the received electric field strength data may be output by a predetermined calculation based on the received electric field strength, and in this way, the detection accuracy of the received electric field strength is increased.
[0151]
(18) The second radio unit may be configured to output the received electric field strength voltage using an amplifier whose input voltage and output voltage have desired characteristics, and in this way, existing circuit components Can be used, and the versatility of parts can be maintained.
(19) The estimation memory may be configured to hold the reception field strength data in consideration of an offset value based on a reference wave having a predetermined characteristic for the reception field strength voltage. Unnecessary computation and circuit scale can be reduced.
[Brief description of the drawings]
FIG. 1 is a configuration diagram of a radio communication system according to a first embodiment of the present invention.
FIG. 2 is a block diagram of a transmission unit of a terminal station according to the first embodiment of the present invention.
FIG. 3 is a block diagram of a multiplex number detection unit and a data generation unit according to the first embodiment of the present invention.
FIG. 4 is a block diagram of a receiving unit of the base station according to the first embodiment of the present invention.
FIG. 5 is a block diagram of a receiving unit of a second radio unit according to the first embodiment of the present invention.
FIG. 6 is a diagram illustrating a format example of a transmission frame.
FIG. 7 is a second block diagram of a multiplex number detection unit and a data generation unit according to the first embodiment of the present invention.
FIG. 8 is a third block diagram of a multiplex number detection unit and a data generation unit according to the first embodiment of the present invention.
FIG. 9 is a block diagram of a transmission unit of a terminal station according to a modification of the first embodiment of the present invention.
FIG. 10 is a block diagram of a receiving unit of a base station according to a modification of the first embodiment of the present invention.
FIG. 11 is a block diagram of a transmission unit of a terminal station according to the second embodiment of the present invention.
FIG. 12 is a block diagram of a transmission unit of a base station according to the second embodiment of the present invention.
FIG. 13 is a diagram illustrating an example of characteristics of an input electric field and an output voltage of a logarithmic amplifier.
FIG. 14 is a diagram illustrating a correspondence between output voltage and received electric field strength.
FIG. 15 is a block diagram illustrating an example of a circuit configuration of a logarithmic amplifier.
FIG. 16 is a diagram showing output voltage offset values related to various input signal waveforms;
FIG. 17 is a diagram illustrating an example of the characteristics of the number of multiplexing and the received electric field strength detection value in an N-CDMA system.
[Explanation of symbols]
1,1a, 1b Terminal station
2,2a, 2b Base station
3, 3a, 3b Wireless communication system
4a exchange
4b network
5,5a, 5b Compensation parameter generator
6, 6a, 6b Compensation parameter output section
11a, 11b antenna
12a First wireless unit
12b Second radio unit
15, 15a, 15b, 36, 36a, 36b Baseband part
16 Coder
17, 17a-17c Data generation part
17-1 to 17-n Transmission data generation unit
18, 18a, 18b Multiplex detection unit
19 First correction memory
14a, 14b Main control unit
20, 20a decoding unit
21 Data demodulator
21c Modulation parameter output unit
22 Estimated memory
23 Correction part
24 1st control part
25 Modulator
26a Correction amount receiving unit (first correction amount output unit)
26b Multiplex receiver (multiplexer detector)
26c Modulation parameter output unit
30, 33a, 33b, 33c Enable number counter
30a, 30c n-ary counter
30b decoder
30d, 31a-31d flip-flop
32a, 32e Band pass filter
32b Low noise amplifier
32c, 32f mixer
32d, 32g Local transmitter
32h low-pass filter
32i, 32j A / D converter
32k RSSI detector
34 Adder
35 Multiplex ROM
37 Memory controller
38 Second correction amount output unit
38a Second correction memory
39 Third correction amount output unit
39a Third correction memory
40a Intercept factor determination unit
40b memory
41 frames
41a Sync signal section
41b, 41d Data signal part
41c Pilot signal section
41e CRC signal part

Claims (5)

A data generation unit that generates and outputs data to be transmitted including control data and information data;
A parameter generator for compensation that outputs a correction amount of a detection error of the reception electric field intensity on the reception side caused by the multiplexing number or the modulation method ;
A coder that encodes the correction amount output from the compensation parameter generator and the data to be transmitted output from the data generator and outputs encoded data;
A terminal station for a radio communication system, comprising: a first radio unit that converts the encoded data output from the coder unit into a radio frequency and outputs a radio signal. A reception main signal obtained by receiving a radio signal including a correction amount of a detection error of a reception electric field intensity on the reception side and transmitted data caused by the multiplexing number or the modulation method, and frequency-converting the radio signal; and the radio A second wireless unit that outputs at least one of the received field strength voltage for the signal;
A decoding unit for outputting a baseband signal resulting from the received main signal output from the second radio unit;
A compensation parameter output unit for outputting received field strength data resulting from the received field strength voltage output from the second wireless unit and the correction amount ;
A correction unit that outputs corrected reception field strength data based on the reception field strength data output from the compensation parameter output unit and the correction amount; and
The baseband signal output from the decoding unit and the data demodulating unit that outputs demodulated data based on the corrected received electric field strength data output from the correcting unit, A base station for a wireless communication system. A plurality of terminal stations that transmit and receive radio signals modulated by a desired radio communication method;
A base station that communicates with the terminal station;
The terminal station
A data generation unit that generates and outputs data to be transmitted including control data and information data;
A parameter generator for compensation that outputs a correction amount of a detection error of the reception electric field intensity on the reception side caused by the multiplexing number or the modulation method ;
A coder that encodes the correction amount output from the compensation parameter generator and the data to be transmitted output from the data generator and outputs encoded data;
A first radio unit that converts the encoded data output from the coder unit into a radio frequency and outputs the radio signal;
further,
The base station
A second radio unit that receives the radio signal and outputs at least one of a reception main signal obtained by frequency-converting the radio signal and a received electric field strength voltage for the radio signal;
A decoding unit for outputting a baseband signal resulting from the received main signal output from the second radio unit;
A compensation parameter output unit for outputting received field strength data resulting from the received field strength voltage output from the second wireless unit and the correction amount ;
A correction unit that outputs corrected reception field strength data based on the reception field strength data output from the compensation parameter output unit and the correction amount; and
The baseband signal output from the decoding unit and the data demodulating unit that outputs demodulated data based on the corrected received electric field strength data output from the correcting unit, Wireless communication system. In a wireless communication system comprising a plurality of terminal stations that transmit and receive a radio signal modulated by a desired wireless communication system, and a base station that communicates with the terminal station,
A modulation step in which the terminal station modulates data to be transmitted for each of one or more transmission channels;
A compensation parameter acquisition step in which the terminal station acquires, for the base station, a correction amount of a detection error of the received electric field strength on the reception side caused by the multiplexing number or the modulation method ;
A transmission step in which the terminal station encodes the data to be transmitted modulated in the modulation step and the correction amount acquired in the compensation parameter acquisition step and transmits encoded data. A received electric field strength compensation method, comprising: In a wireless communication system comprising a plurality of terminal stations that transmit and receive a radio signal modulated by a desired wireless communication system, and a base station that communicates with the terminal station,
A reception step in which the base station receives a radio signal having a correction amount of a detection error of a reception electric field strength on the reception side caused by the multiplexing number or the modulation method ;
A detecting step in which the base station detects a received electric field strength of the radio signal received in the receiving step;
The base station corrects a detection error of the reception electric field strength based on the correction amount included in the radio signal received in the reception step and the reception electric field strength detected in the detection step. A received electric field strength compensation method, comprising: a correction step.

Images