JP3423528B2 - Digital mobile communication system - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a digital mobile communication system for eliminating an imbalance between an upstream radio communication line and a downstream radio communication line for a mobile station during a call.

[0002]

2. Description of the Related Art As a conventional digital mobile communication system, for example, an exchange station which accommodates a plurality of base stations and which makes communication connection between mobile stations and between a mobile station and a fixed station, and a plurality of exchange stations accommodated in the exchange station are provided. There is known a system including a base station and a plurality of mobile terminals which are mobile stations.

FIG. 10 is a block diagram of a conventional mobile station disclosed in, for example, Japanese Patent Laid-Open No. 63-61516, FIG. 11 is a block diagram of a conventional base station, and FIG. 12 is a block diagram of a conventional exchange station. 1
3 is a diagram showing a conventional signal format. FIG. 14 is a diagram showing an outline of the entire digital mobile communication system.

In FIG. 10, reference numeral 80a is a mobile station and 81a.
Is a microphone, 82a is an A / D converter, 83a is an encoding circuit, 84a is a level determination circuit, 85a is a modulator, 86
a is an amplifier circuit, 87a is a demodulation and decoding circuit, and 88a
Antenna, 89a is tuned amplifier, 90a is D / A conversion and amplification unit, 91a denotes a speaker.

Further, in FIG. 11, 80c is a base station,
81c is an amplification circuit, 82c is a modulator, 83c is a tuning amplifier, 84c is a demodulation circuit, 85c is a level measurement circuit, and 86.
c indicates a base station controller.

Further, in FIG. 12, 80b is an exchange station,
81b is an encoding circuit, 83b is a control signal detecting / decoding circuit, 84b is a level judging circuit, 85b is a level control circuit, and 86b is a time division switch.

[0007] Incidentally, in FIG. 13, 81D～87d are signals constituting a wireless communication line, a subtilase catcher, channel,
81d is a frame synchronization pattern, 82d is level data, 83d is audio data, 84d is an identifier, 85d is a received electric field strength, 86d is an identifier, and 87d is a transmission electric field strength. These signals are repeatedly transmitted as one cycle (one frame). Further, in FIG. 14, 81e is a switching center, 82e is a base station accommodated in the switching center 81e,
Mobile station 3e is capable of communicating through switching station 81e, 84e are downlink radio control channel, 85e uplink radio system
Control line, 86e is a downlink radio communication line, 87e is an uplink radio
A call line, 88e is a sub-channel connected from the base station to the exchange, and 89e is an extension terminal which is a call partner of the mobile station 83e, for example.

Next, the operation of the above configuration will be described in the order of (a) upstream voice flow, (a) downstream voice flow, and (c) transmission output determination method.

(A) Upstream voice flow The voice input from the microphone 81a of the mobile station is digitized by the A / D converter 82a and transmitted to the base station 80c through the modulator 85a, the amplification circuit 86a and the antenna 88a. . The midway encoding circuit 83a provides the signal configuration shown in FIG. The encoding circuit 83a receives the level data from the level determination circuit 84a and superimposes it on a wireless communication line (described later). Further, the transmission output at this time is set to a value instructed by the decoding circuit 87a to the amplification circuit 86a.

The base station 80c measures the electric field strength of the received uplink radio communication line and notifies the exchange 80b through the sub-channel 88e.

The exchange 80b sends the upstream radio communication line data to the partner terminal 89e. Further, the switching center 80b uses the information 8 of the electric field strength of the uplink radio communication line from the sub-channel 88e.
5d is received by the level determination circuit 84b and sent as level data to the transmission side encoding circuit 81b. Furthermore, the level data 82d superimposed on the upstream radio communication line
After being received by the decoding circuit 82b, the level control circuit instructs the base station 80c to perform transmission output using the subchannel.

The exchange 80b can also identify and receive the control signal superimposed on the radio communication line by the control signal detection / decoding circuit 83b.

(B) Downstream voice flow The voice from the other terminal 89e side is passed to the base station 80c by the encoding circuit 81b in the exchange 80b having the signal structure shown in FIG. At this time, the level determination circuit 84b
The level data sent from is superposed on the downlink communication line. The base station 80c transmits a radio wave to the mobile station 80a with the transmission output instructed by the exchange 80b.

The mobile station 80a receives the radio wave, converts the voice data into analog by the D / A converter 90a, and outputs it through the speaker 91a. At the same time, the electric field strength of the downlink radio communication line is measured by the level determination circuit 84a and is notified to the transmission side encoding circuit 83a as level data.
Further, the level data 82d in the downlink wireless communication line is analyzed by the decoding circuit 87a, and the amplification circuit 86a is instructed to perform transmission output. The amplifier circuit 86a transmits with the instructed transmission output.

(C) Transmission output determination method A specific transmission output determination method in the decoding circuit is described in Japanese Patent Laid-Open No. 4-92518.
When the received electric field information is small, the transmission output is increased by that amount, so that the transmission output is increased or decreased in inverse proportion to the value of the level data.

[0016]

In the prior art, the transmission output of the mobile station and the base station is controlled by passing the electric field strength information to the other side in this way, so that the mobile station is out of the service area. When moving away from the base station, there is a problem that the transmission output of the mobile station is unnecessarily increased, and even if the mobile station is in a short distance from the base station, only the downlink electric field does not reach. In such a case, there is a problem in that the one-way call remains as it is or a handover is performed to a distant base station.

In other words, there is a problem that the transmission output is unnecessarily increased when an imbalance occurs in the up / down electric field strength.

The present invention has been made to solve the above-mentioned problems, and eliminates the imbalance of the up / down electric field with respect to the mobile station during a call and realizes a call with less power. The purpose is to obtain a digital mobile communication system.

[0019]

In order to achieve the above object, a digital mobile communication system according to the present invention comprises:
From a switching center that accommodates a plurality of base stations and performs communication connection between mobile stations and between a mobile station and a fixed station, a plurality of base stations accommodated in the switching center, and a plurality of mobile terminals that are mobile stations, A first level data superimposing means configured to measure the electric field strength of the downlink radio communication line and superimpose and transmit as level data 1 on the uplink radio communication line by the mobile station; A first transmission output control means for analyzing the value of the level data superimposed on the line and controlling the transmission output, wherein the switching center measures the electric field strength of the uplink radio communication line and the downlink radio call. Level data 2 on the line
Second level data superimposing means for superimposing and transmitting as a base station, and second transmission output control for controlling the transmission output of the base station by analyzing the value of the level data superimposed on the upstream radio communication line by the mobile station. in digital mobile communication system comprising: means, wherein the mobile station, have a number of bit errors superimposing means for superimposing in the uplink radio speech channel audio frame to calculate the number of bit errors in the downlink radio speech channel audio frame , The second transmission output control means receives the
Wireless communication line voice frame from the mobile station bit error
Extracts the number of bit errors placed by the number superposition means
However, depending on the value and the value of the level data 1, the current
Controls the transmission output in multiple stages to continue the call on the line
Or transmit power to prompt handover
To control.

In the digital mobile communication system according to the present invention, in the mobile station, the bit error number superimposing means calculates the number of bit errors in the downlink radio communication line voice frame and superimposes it in the uplink radio communication line voice frame . Also, this
A digital mobile communication system according to the invention of
In addition, the uplink voice communication line audio frame received from the mobile station
Output from the base station by extracting the number of bit errors from the system
Is controlled in multiple stages. Therefore, as the data on the uplink radio communication line sent from the mobile station, it is possible to further fine transmission power control by adding the number of bit errors in the downlink radio speech channel audio frame. That is,
If the bit error is large despite the strong electric field, the transmission output can be reduced to a level that prompts handover, and even if the electric field is small, the transmission output can be further reduced if there is no bit error.

[0021]

[0022]

In a digital mobile communication system according to the next invention, an exchange station for accommodating a plurality of base stations to establish a communication connection between mobile stations and between a mobile station and a fixed station, and a plurality of bases accommodated in the exchange station. Station, and a plurality of mobile terminals that are mobile stations,
A first level data superimposing means for measuring the electric field strength of the downlink radio communication line and superimposing and transmitting the level data as level data 1 on the uplink radio communication line.
A first transmission output control means for controlling the transmission output by analyzing the value of the level data superimposed on the downlink radio communication line by the exchange, wherein the exchange has the electric field strength of the uplink radio communication line. Second level data superimposing means for measuring and measuring and transmitting as level data 2 on the downlink radio communication line, and the base station by analyzing the value of the level data superimposed on the uplink radio communication line by the mobile station. In a digital mobile communication system having a second transmission output control means for controlling the transmission output of the station, the switching center calculates the number of bit errors in the voice frame of the uplink radio communication line, and the voice communication of the downlink radio communication line. have a number of bit errors superimposing means for superimposing in a frame, said first transmission power control means receives
From the downlink wireless communication line voice frame
The number of bit errors carried by the error number superimposing means is calculated.
Depending on the value and the value of the level data 2
Multiple levels of transmission output to continue the call on the existing line
Send to control or prompt handover
It controls power.

In the digital mobile communication system according to the present invention, in the exchange, the bit error number superimposing means calculates the number of bit errors in the upstream radio communication line voice frame and superimposes it in the downstream radio communication line voice frame . Also, this
A digital mobile communication system according to the invention of
In addition, the upstream wireless communication line voice frame received from the exchange
The number of bit errors is extracted from the system and its value and level
The transmission output is controlled in a plurality of stages according to the value of the data 2. And <br/> was Therefore, as the data on the downlink radio communication line sent from the exchange, it is possible to further fine transmission power control by adding the number of bit errors in the uplink radio speech channel audio frame. That is, if the bit error is large despite the strong electric field, the transmission output can be reduced to a level that prompts handover, and even if the electric field is small, the transmission output can be further reduced if there is no bit error.

[0025]

[0026]

In the digital mobile communication system according to the next invention, an exchange station that accommodates a plurality of base stations and establishes communication connection between mobile stations and between a mobile station and a fixed station, and a plurality of bases accommodated in the exchange station. Station, and a plurality of mobile terminals that are mobile stations,
A first level data superimposing means for measuring the electric field strength of the downlink radio communication line and superimposing and transmitting the level data as level data 1 on the uplink radio communication line.
A first transmission output control means for controlling the transmission output by analyzing the value of the level data superimposed on the downlink radio communication line by the exchange, wherein the exchange has the electric field strength of the uplink radio communication line. Second level data superimposing means for measuring and measuring and transmitting as level data 2 on the downlink radio communication line, and the base station by analyzing the value of the level data superimposed on the uplink radio communication line by the mobile station. In a digital mobile communication system having a second transmission output control means for controlling the transmission output of the station, the switching center superimposes the transmission power class information of the base station on the downlink radio communication line. have a superimposing unit, the first transmission output
Whether the control means is the received downlink wireless communication line voice frame
From the base station transmission output class information superimposing means.
The sent output class information is extracted and its value and
Depending on the measured electric field strength, the relative position from the base station
Estimate and transmit power in multiple stages based on the estimation result
To control.

In the digital mobile communication system according to the present invention, in the exchange, the transmission output class information superimposing means superimposes the transmission output class information of the base station on the downlink radio communication line. As a result, the transmission output class information of the base station is passed from the exchange to the mobile station. Also, this invention
The digital mobile communication system by
From the received downlink wireless communication line voice frame to the base station
Send output class information of and send according to its value
Control the output in multiple stages.

[0029]

[0030]

In the digital mobile communication system according to the next invention, an exchange station for accommodating a plurality of base stations to establish communication connection between mobile stations and between a mobile station and a fixed station, and a plurality of bases accommodated in the exchange station. Station, and a plurality of mobile terminals that are mobile stations,
A first level data superimposing means for measuring the electric field strength of the downlink radio communication line and superimposing and transmitting the level data as level data 1 on the uplink radio communication line.
A first transmission output control means for controlling the transmission output by analyzing the value of the level data superimposed on the downlink radio communication line by the exchange, wherein the exchange has the electric field strength of the uplink radio communication line. Second level data superimposing means for measuring and measuring and transmitting as level data 2 on the downlink radio communication line, and the base station by analyzing the value of the level data superimposed on the uplink radio communication line by the mobile station. In a digital mobile communication system having a second transmission output control means for controlling the transmission output of the station, the first transmission output control means has the electric field strength of the downlink radio communication line below a certain value during a call. In this case, the transmission output is lowered to a level at which handover is started while monitoring the electric field strength of the uplink radio communication line notified on the downlink radio communication line.

In the digital mobile communication system according to the present invention, when the electric field strength of the downlink radio communication line falls below a certain value during a call in the mobile station, the electric field of the uplink radio communication line is notified on the downlink radio communication line. The transmission output is reduced to a level at which handover is started while monitoring the strength.

In the digital mobile communication system according to the next invention, an exchange station for accommodating a plurality of base stations to establish a communication connection between mobile stations and between a mobile station and a fixed station, and a plurality of bases accommodated in the exchange station. Station, and a plurality of mobile terminals that are mobile stations,
A first level data superimposing means for measuring the electric field strength of the downlink radio communication line and superimposing and transmitting the level data as level data 1 on the uplink radio communication line.
A first transmission output control means for controlling the transmission output by analyzing the value of the level data superimposed on the downlink radio communication line by the exchange, wherein the exchange has the electric field strength of the uplink radio communication line. Second level data superimposing means for measuring and measuring and transmitting as level data 2 on the downlink radio communication line, and the base station by analyzing the value of the level data superimposed on the uplink radio communication line by the mobile station. In a digital mobile communication system having a second transmission output control means for controlling the transmission output of the station, the mobile station has a downlink electric field strength below a certain value during a call, and on a downlink radio communication line. A switching control signal transmitting means for transmitting to the switching center a switching control signal requesting switching of the communication channel within the zone when the electric field strength of the notified upstream radio communication line is sufficiently high. It is intended.

In the digital mobile communication system according to the present invention, in the mobile station, the downlink electric field strength is below a certain value during a call, and the electric field strength of the uplink radio communication line notified on the downlink radio communication line is sufficiently large. At this time, the mobile station transmits a switching control signal requesting switching of the communication channel within the zone to the exchange.

In a digital mobile communication system according to the next invention, an exchange station for accommodating a plurality of base stations to establish a communication connection between mobile stations and between a mobile station and a fixed station, and a plurality of bases accommodated in the exchange station. Station, and a plurality of mobile terminals that are mobile stations,
A first level data superimposing means for measuring the electric field strength of the downlink radio communication line and superimposing and transmitting the level data as level data 1 on the uplink radio communication line.
A first transmission output control means for controlling the transmission output by analyzing the value of the level data superimposed on the downlink radio communication line by the exchange, wherein the exchange has the electric field strength of the uplink radio communication line. Second level data superimposing means for measuring and measuring and transmitting as level data 2 on the downlink radio communication line, and the base station by analyzing the value of the level data superimposed on the uplink radio communication line by the mobile station. In a digital mobile communication system having a second transmission output control means for controlling the transmission output of the station, the mobile station has a downlink electric field strength below a certain value during a call, and on a downlink radio communication line. A visual notification means is provided to notify the user when the electric field strength of the uplink radio communication line to be notified is sufficiently high.

In the digital mobile communication system according to the present invention, in the mobile station, the downlink electric field strength is below a certain value during a call, and the electric field strength of the uplink radio communication line notified on the downlink radio communication line is sufficiently large. When it becomes, the user is notified through the visual notification means. Therefore, the user can easily recognize the state of the mobile station.

In a digital mobile communication system according to the next invention, an exchange station for accommodating a plurality of base stations to establish communication connection between mobile stations and between a mobile station and a fixed station, and a plurality of bases accommodated in the exchange station are provided. Station, and a plurality of mobile terminals that are mobile stations,
A first level data superimposing means for measuring the electric field strength of the downlink radio communication line and superimposing and transmitting the level data as level data 1 on the uplink radio communication line.
A first transmission output control means for controlling the transmission output by analyzing the value of the level data superimposed on the downlink radio communication line by the exchange, wherein the exchange has the electric field strength of the uplink radio communication line. Second level data superimposing means for measuring and measuring and transmitting as level data 2 on the downlink radio communication line, and the base station by analyzing the value of the level data superimposed on the uplink radio communication line by the mobile station. In a digital mobile communication system having a second transmission output control means for controlling the transmission output of the station, the mobile station has a downlink electric field strength below a certain value during a call, and on a downlink radio communication line. It has a warning means for generating a warning sound to notify the user when the electric field strength of the notified upstream radio communication line is sufficiently high.

In the digital mobile communication system according to the present invention, in the mobile station, the downlink electric field strength is below a certain value during a call, and the electric field strength of the uplink radio communication line notified on the downlink radio communication line is sufficiently high. When it becomes, a warning sound is generated by the warning means to notify the user. Therefore, the user can easily recognize the state of the mobile station.

In the digital mobile communication system according to the next invention, the mobile station has a downlink electric field strength below a certain value during the call, and the electric field strength of the uplink radio communication line notified on the downlink radio communication line. Is sufficiently large, a switching request signal transmitting means for transmitting a call channel switching request signal within the zone is provided.

In the digital mobile communication system according to the present invention, in the mobile station, the downlink electric field strength is below a certain value during a call, and the electric field strength of the uplink radio communication line notified on the downlink radio communication line is sufficiently large. In this case, the switching request signal transmitting means transmits the call channel switching request signal in the zone from the mobile station to the exchange.

[0041]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the accompanying drawings.

[Embodiment 1] FIG. 1 is a block diagram of a mobile station constituting Embodiment 1 of a digital mobile communication system according to the present invention. Mobile station 10 according to the first embodiment
In a, the voice (that is, the upstream radio communication line) input from the microphone 11a is digitized by the A / D converter 12a, and the encoding circuit 13a, the modulator 15a,
Base station 10c through amplifier circuit 16a and antenna 18a
Sent to. At this time, the encoding circuit 13a receives the level data from the level determination circuit 14a, which will be described later, and also receives the set number of bits from the error correction / error number calculation circuit 22a, and superimposes it on the upstream radio communication line.

On the other hand, the downlink radio communication line has an antenna 18
It enters from a, passes through the tuning amplifier 19a, the demodulation circuit 17a, and the data read circuit 23a and enters the error correction / error number calculation circuit 22a. Since the voice data transmitted and received on the wireless line (that is, the downlink wireless communication line) is encoded for error correction, the number of bits corrected and decoded by the error correction / error number calculation circuit 22a is shown. calculate.

The bit error number calculated by the error correction / error number calculation circuit 22a is notified to the encoding circuit 13a as error number data 13d (see FIG. 3), and the level data notified from the level determination circuit 14a by the encoding circuit 13a. 12d (see FIG. 3) is superimposed on the upstream radio communication line.

The voice data decoded by the error correction / error number calculation circuit 22a is D / A converted and amplified by the amplifier 20.
It is converted into an analog signal by a and output through the speaker 21a.

The transmission output control of the mobile station 10a, that is, the output control of the amplifier circuit 16a is performed by the transmission output control circuit 24a. Specifically, the transmission output control circuit 24a inputs the level data 12d and the error number data 13d on the downlink radio control circuit extracted by the data reading circuit 23a, and sets them as two parameters of the level data and the error number data. Based on this, the optimum transmission output value is selected, and the amplifier circuit 16a is controlled to control the transmission output.

FIG. 2 shows a block diagram of an exchange station constituting the first embodiment of the digital mobile communication system according to the present invention. Further, FIG. 3 shows a configuration of a radio communication line (uplink and downlink) used in the digital mobile communication system of the present invention.

The upstream radio communication line configured as shown in FIG. 3 enters the exchange 10b, the level data / error number data reading circuit 12b reads the level data 12d and the error number data 13d, and reads them. The output data enters the level control circuit 15b. Level control circuit 15b
Then, the optimum transmission output value is selected based on the two parameters of the level data and the error number data, and the transmission output of the base station (not shown) is controlled through the subchannel.

Further, the upstream radio communication line enters the error correction / error number calculation circuit 17b after passing through the level data / error number data reading circuit 12b. The voice data is encoded for error correction, and the error correction / error number calculation circuit 17
The number of bits that has been decoded and corrected in b is calculated. The calculated bit error number is notified to the encoding circuit 11b as the error number data 13d, and the encoding circuit 11b is notified.
b is superposed on the downlink radio communication line together with the level data 12d notified from the level determination circuit 14b.

In the figure, 16b represents a time divisional switch. The exchange 10b can also identify and receive the control signal superimposed on the wireless communication line by the control signal detection / decoding circuit 13b.

In the digital mobile communication system of the first embodiment, the configuration of the base station is not particularly limited, and the configuration of the base station of the conventional digital mobile communication system shown in FIG. 11 can be applied. Illustration and description are omitted.

The transmission output control of the first embodiment having the above configuration will be described.

First, in the first embodiment, the mobile station 10
It is assumed that the transmission output (S) of a and the base station can be controlled in three stages of S1 <S2 <Smax. In addition, the level data (R) is displayed in five stages of R1 (level at which the call is interrupted) <R2 (level for promoting handover) <R3 <R4 <R5, and the number of bit errors (B) is 0 <B1 (impacts the call. There is no range) <B2 (range that affects the call).

Next, the transmission output (S) of the mobile station 10a and the base station is calculated from the level data (R) displayed in five stages and the bit error number (B) displayed in three stages as described above.
Is controlled based on the following conditions.

When R = R1, S is increased by one step. When R = R2 and B = B1 and B2, S is increased by one step. When R = R2 and B = 0, S is left unchanged. When R = R3, R4 and B = B2, S (transmission output) is lowered so that R = R2. When R = R3, B = 0, and B1, S is left unchanged. When R = R4, B = 0, B1, S is lowered by one step. When R = R5, S is lowered by one step.

That is, in the case of 1, since the electric field reaching is too small, the transmission output is increased by one step. In the case of 1, since the bit error has reached a large electric field, the transmission output is increased by one step. In the case of 1, the electric field reaching is small, but there is no bit error and it does not affect the call. Therefore, the transmission output is left unchanged. In case of 1, the electric field reaching is sufficient, but the bit error is large and it seems that there is an abnormality in the channel. Therefore, the transmission output is reduced to the arrival level that prompts handover. In the case of, the electric field level and the bit error are good, and the transmission output is left unchanged. In the case of 1, since there is no bit error and the reaching electric field is large, the transmission output is lowered by one stage. In the case of 1, since the electric field level that has reached is too large, the transmission output is lowered by one step.

Since the mobile station and the switching station are configured as described above and the number of bit errors which actually causes a problem in the call is used as the parameter for controlling the transmission output, the up / down call state The imbalance can be eliminated and the mobile station can realize communication with smaller power.

[Embodiment 2] In the digital mobile communication system of Embodiment 2, base station information (transmission output class information of the base station) is placed on the downlink radio communication line, and the base station information is set in the mobile station. The transmission output is determined from the received electric field strength and the received electric field strength.

FIG. 4 shows base station information 1 on the downlink radio communication line.
It is an example in which 3e is superimposed. FIG. 5 is a block diagram of the mobile station 30a according to the second embodiment, which determines the transmission output from the base station information 13e and the received electric field strength.

In FIG. 5, 31a is a microphone and 3a.
2a is an A / D converter, 33a is an encoding circuit, 34a
Is a level determination circuit, 35a is a modulator, 36a is an amplifier circuit, 37a is a demodulation and decoding circuit, 38a is an antenna, 39a is a tuning amplifier, 40a is D / A conversion and amplification.
Vessel, 41a is a speaker, 42a denotes a transmission output control circuit.

The operation of mobile station 30a of the second embodiment having the above configuration will be described. The received downlink radio communication line enters the demodulation and decoding circuit 37a. here,
The level data 12e and the base station information 13e are read out and sent to the transmission output control circuit 42a.

On the other hand, the downlink radio communication line also enters the level judgment circuit 34a, and the reception electric field level measured here is notified to the encoding circuit 33a as well as the transmission output control circuit 42a as in the conventional case.

The transmission output control circuit 42a determines the transmission output based on the three parameters of the level data 12e, the base station information 13e, and the reception electric field level, and controls the amplification circuit 36a.

The base station information 13e is mainly the value of the maximum transmission output of the base station. For example, set the maximum transmission output (P) to P1
(= Smax) <P2 <P3 in three stages, the reception electric field strength (J) is J1 <J2 (level to promote handover) <J
3 (good) <J4 in four stages, and the transmission output (S) of the mobile station 30a can be controlled in three stages of S1 <S2 <Smax, the following can be controlled.

When J = J1, S = Smax. When P = P3 and J = J2, S = Smax. When P = P3 and J = J3, S = S2. When P = P2, J = J2, and J3, S = S2. When P = P1 and J = J2, S = S2. When P = P1 and J = J3, S = S1. When J = J4, S = S1.

Since the maximum transmission output of the base station is used as the parameter for controlling the transmission output of the mobile station in this way, the transmission output is determined by estimating the relative position from the base station from this and the strength of the received electric field. You can In addition, JP-A-3-321
In the publication No. 22, the base station information is sent using the wireless control line, but if the base station information is sent using the wireless communication line as in the present invention, when the zone is moved without going through the wireless control line ( Similar control can be performed at the destination even in the case of handover or the like).

[Third Embodiment] A digital mobile communication system according to a third embodiment has the same configuration as that of the second embodiment and shows an example of controlling the transmission output when the transmission output of the mobile station is larger than that of the base station. Show.

In the case of a mobile station whose transmission output is larger than that of the base station, the transmission output can be controlled as follows. That is, when J = J1 (reception electric field becomes smaller than a certain fixed value) using the reception electric field strength (J) and level data (R) as parameters, transmission is performed so that R = R2 (level to promote handover). Lower the output (S).

Since the mobile station controls the transmission output in this way, the mobile station located at the edge of the area where the downstream radio wave does not reach can perform handover of the switching center matter without increasing the transmission output.

[Fourth Embodiment] The digital mobile communication system according to the fourth embodiment switches the communication channel when the downlink electric field falls below a certain value although the uplink electric field is sufficient for some reason. It is a switch.

FIG. 6 is a block diagram of a mobile station which constitutes a fourth embodiment of the digital mobile communication system according to the present invention. In FIG. 6, the portions corresponding to those in FIG. 5 are designated by the same reference numerals as those in FIG. 5, and the description thereof will be omitted.

That is, the demodulation and decoding circuit 37a
Control signal generating circuit information (R) Luo level data 42 b
To the received electric field strength (J) from the level determination circuit 34a.
Send a control signal generating circuit 42 b. Control signal generation circuit 4
2b generates a control signal for requesting handover (switching of communication line) within the zone and sends it to the encoding circuit 33a when R is sufficiently large and J falls below a certain value. The encoding circuit 33a transmits the control signal on the uplink wireless communication line as a substitute for voice data. On the exchange side, the control signal detection / decoding circuit 83b shown in FIG. 12 receives and receives the necessary processing.

As a result, when the downlink electric field falls below a certain value despite the fact that there is a sufficient uplink electric field due to some factor, the call channel is switched to switch both the uplink wireless call line and the downlink wireless call line. You can keep good.

[Fifth Embodiment] FIG. 7 is a block diagram of a mobile station constituting a fifth embodiment of a digital mobile communication system according to the present invention. In addition, in FIG. 7, portions corresponding to those in FIG. 6 are denoted by the same reference numerals as those in FIG. 6, and description thereof will be omitted.

In the above-described fourth embodiment, the mobile station automatically transmits the intra-zone handover request control signal, but in the fifth embodiment, the mobile station 50a is configured as shown in FIG. The lamp 52a informs the operator of the state in which a handover is required, and the operator can send a control signal by pressing the button 51a. FIG. 8 shows an example of the external appearance of the mobile station 50a provided with the button 51a and the lamp 52a.

[Sixth Embodiment] FIG. 9 is a block diagram of a mobile station constituting a sixth embodiment of the digital mobile communication system according to the present invention. In addition, in FIG. 9, portions corresponding to those in FIG. 7 are denoted by the same reference numerals as those in FIG. 7, and description thereof will be omitted.

In the above-mentioned fifth embodiment, the means for notifying the operator by the lamp is used, but this may be done also by the tone. In the sixth embodiment, the mobile station 60a is constructed as shown in FIG. Control signal generation circuit 4
A tone is generated from 2b, mixed with voice in the adder circuit 61a, and output from the speaker 41a.

[0078]

As is clear from the above description, in the mobile station, the bit error number superimposing means calculates the number of bit errors in the downlink radio communication line voice frame and superimposes it in the uplink radio communication line voice frame. Therefore, it is possible to perform more detailed transmission output control, and if the bit error is large despite the strong electric field, the transmission output can be reduced to a level that prompts handover. The output can be reduced.
That is, it is possible to eliminate the imbalance of the up / down electric field with respect to the mobile station during the call, and to realize the call with less power.

In the digital mobile communication system according to the next invention, the exchange station extracts the bit error number from the uplink radio communication line voice frame received from the mobile station and controls the transmission output of the base station in a plurality of steps. It is possible to eliminate the imbalance of the up / down electric field with respect to the mobile station during the call, and to realize the call with less power.

In the digital mobile communication system according to the next invention, in the exchange, the bit error number superimposing means calculates the number of bit errors in the upstream radio communication line voice frame and superimposes it in the downstream radio communication line voice frame. Therefore, it is possible to eliminate the imbalance of the up / down electric field with respect to the mobile station during the call, and to realize the call with less power.

In the digital mobile communication system according to the next invention, the mobile station extracts the bit error number from the upstream radio communication line voice frame received from the exchange and transmits the output according to the value and the value of the level data 2. Since it is controlled in a plurality of steps, it is possible to eliminate the imbalance of the up / down electric field with respect to the mobile station during the call, and to realize the call with less power.

In the digital mobile communication system according to the next invention, in the exchange, the transmission output class information superimposing means superimposes the transmission output class information of the base station in the downlink radio communication line. Information is passed from the mobile switching center to the mobile station, which enables finer control of the transmission power, eliminates the imbalance of the up / down electric field for the mobile station during the call, and enables the call with less power. it can.

In the digital mobile communication system according to the next invention, the mobile station extracts the transmission output class information of the base station from the received downlink radio communication line voice frame,
Since the transmission output is controlled in multiple stages according to the value, more precise transmission output control is possible, eliminating the imbalance of the up / down electric field to the mobile station during the call and realizing the call with less power. can do.

In the digital mobile communication system according to the next invention, when the electric field strength of the downlink radio communication line is below a certain value during a call in the mobile station, the uplink radio communication line is notified on the downlink radio communication line. Since the transmission output is lowered to the level at which handover is started while monitoring the electric field strength, it is possible to eliminate the imbalance of the up / down electric field with respect to the mobile station in the call, and to realize the call with less power.

In the digital mobile communication system according to the next invention, in the mobile station, the downlink electric field strength is below a certain value during a call, and the electric field strength of the uplink radio communication line notified on the downlink radio communication line is sufficient. When the value is large, the mobile station transmits a switching control signal requesting the switching of the call channel in the zone to the exchange station. Therefore, while eliminating the imbalance of the up / down electric field with respect to the mobile station in the call,
A call can be realized with less power.

In the digital mobile communication system according to the next invention, in the mobile station, the downlink electric field strength is below a certain value during a call, and the electric field strength of the uplink radio communication line notified on the downlink radio communication line is sufficient. When the size of the mobile station becomes large, the user is notified via the visual notification means, so that the user can easily recognize the state of the mobile station.

In the digital mobile communication system according to the next invention, in the mobile station, the downlink electric field strength is below a certain value during a call, and the electric field strength of the uplink radio communication line notified on the downlink radio communication line is sufficient. When the size becomes large, a warning sound is generated by the warning means to notify the user, so that the user can easily recognize the state of the mobile station.

In the digital mobile communication system according to the next invention, in the mobile station, the downlink electric field strength is below a certain value during a call, and the electric field strength of the uplink radio communication line notified on the downlink radio communication line is sufficient. When it becomes large, in order to transmit the call channel switching request signal in the zone from the mobile station to the exchange by the switching request signal transmitting means,
It is possible to eliminate the imbalance of the up / down electric field with respect to the mobile station during the call, and to realize the call with less power.

[Brief description of drawings]

FIG. 1 is a configuration diagram of a mobile station which constitutes a first embodiment of a digital mobile communication system according to the present invention.

FIG. 2 is a configuration diagram of a switching center which constitutes the first embodiment of the digital mobile communication system according to the present invention.

FIG. 3 is an explanatory diagram showing a configuration of a wireless communication line (uplink and downlink) used in the first embodiment of the digital mobile communication system of the present invention.

FIG. 4 is an explanatory diagram showing a configuration of a downlink radio communication line on which base station information used in Embodiment 2 of the digital mobile communication system of the present invention is superimposed.

FIG. 5 is a configuration diagram of a mobile station which constitutes a second embodiment of the digital mobile communication system according to the present invention.

[Fig. 6] Fig. 6 is a configuration diagram of a mobile station which constitutes a fourth embodiment of the digital mobile communication system according to the present invention.

FIG. 7 is a configuration diagram of a mobile station which constitutes a fifth embodiment of the digital mobile communication system according to the present invention.

FIG. 8 is an explanatory diagram showing an example of an external appearance of a mobile station with buttons and lamps according to a fifth embodiment.

FIG. 9 is a configuration diagram of a mobile station which constitutes a sixth embodiment of the digital mobile communication system according to the present invention.

FIG. 10 is an explanatory diagram showing a configuration of a mobile station of a conventional digital mobile communication system.

FIG. 11 is an explanatory diagram showing a configuration of a base station of a conventional digital mobile communication system.

FIG. 12 is an explanatory diagram showing a configuration of a switching center of a conventional digital mobile communication system.

13 is an explanatory view showing a configuration of a conventional radio communication lines and subtilis catcher, channel.

FIG. 14 is a diagram showing an outline of an entire conventional digital mobile communication system.

[Explanation of symbols]

10a mobile station, 11a microphone, 12a A / D converter, 13a encoding circuit, 15 modulator, 16a
Amplifier circuit, 17a Demodulator circuit, 18a Antenna, 19
a tuning amplifier, 20a D / A conversion and amplifier, 21
a speaker, 22a error correction / error number calculation circuit, 2
3a data reading circuit, 24a transmission output control circuit,
10b exchange station, 11b encoding circuit, 12b level data / error number data reading circuit, 13b control signal detection / decoding circuit, 14b level determination circuit, 15b
Level control circuit, 16b time division switch, 17b error correction / error number calculation circuit, 11d frame synchronization pattern, 12d level data, 13d error number data, 1
4d audio data, 11e frame synchronization pattern, 1
2e level data, 13e base station information, 14e voice data, 30a mobile station, 31a microphone, 32a A
/ D converter, 33a encoding circuit, 34a level determination circuit, 35a modulator, 36a amplification circuit, 37a
Demodulation and decoding circuit, 38a antenna, 39a
Tuned amplifier, 40a D / A conversion and amplification unit, 41a
Speaker, 42a transmission output control circuit, 42b control signal generation circuit, 50a mobile station, 51a button, 52a
lamp

─────────────────────────────────────────────────── ─── Continuation of the front page (58) Fields surveyed (Int.Cl. ⁷ , DB name) H04B ^7/ 24-7/26 H04Q ⁷ /00-7/38

Claims (8)

(57) [Claims] 1. An exchange station that accommodates a plurality of base stations and performs communication connection between mobile stations and between a mobile station and a fixed station, a plurality of base stations accommodated in the exchange station, and a plurality of mobile stations. A mobile terminal, wherein the mobile station measures the electric field strength of the downlink radio communication line, superimposes it as level data 1 on the uplink radio communication line and transmits it, and the exchange. First transmission output control means for controlling the transmission output by analyzing the value of the level data superimposed on the downlink wireless communication line by the station;
The exchange station measures the electric field strength of the uplink radio communication line and superimposes and transmits as level data 2 on the downlink radio communication line; and the mobile station transmits the uplink radio data. A digital mobile communication system comprising: a second transmission output control means for controlling a transmission output of the base station by analyzing a value of level data superimposed on a communication line, wherein the mobile station is a downlink wireless communication line. calculating the number of bit errors in the speech frames have a number of bit errors superimposing means for superimposing in the uplink radio communication line speech frames, the second transmission power control means, uplink radio call received
Bit error number superimposing hand of the mobile station from the line voice frame
The number of bit errors placed by the stage is extracted and its value
And call on the current line according to the value of level data 1 above
Control the transmission output in multiple stages to
In addition , a digital mobile communication system characterized by controlling a transmission output in order to promote handover . 2. An exchange station that accommodates a plurality of base stations and performs communication connection between mobile stations and between a mobile station and a fixed station, a plurality of base stations accommodated in the exchange station, and a plurality of mobile stations. A mobile terminal, wherein the mobile station measures the electric field strength of the downlink radio communication line, superimposes it as level data 1 on the uplink radio communication line and transmits it, and the exchange. First transmission output control means for controlling the transmission output by analyzing the value of the level data superimposed on the downlink wireless communication line by the station;
The exchange station measures the electric field strength of the uplink radio communication line and superimposes and transmits as level data 2 on the downlink radio communication line; and the mobile station transmits the uplink radio data. In a digital mobile communication system comprising: second transmission output control means for controlling a transmission output of the base station by analyzing a value of level data superimposed on a communication line, the exchange station is an uplink wireless communication line. have a number of bit errors superimposing means for superimposing calculate the number of bit errors in the speech frames during downlink radio speech channel audio frame, the first transmission power control means, downlink radio call received
Bit error number superimposing hand of the exchange from the line voice frame
The number of bit errors placed by the stage is extracted and its value
And the current line depending on the level data 2 value
Control the transmission output in multiple stages to
In addition , a digital mobile communication system characterized by controlling a transmission output in order to promote handover . 3. An exchange station accommodating a plurality of base stations for performing communication connection between mobile stations and between a mobile station and a fixed station, a plurality of base stations accommodated in the exchange station, and a plurality of mobile stations. A mobile terminal, wherein the mobile station measures the electric field strength of the downlink radio communication line, superimposes it as level data 1 on the uplink radio communication line and transmits it, and the exchange. First transmission output control means for controlling the transmission output by analyzing the value of the level data superimposed on the downlink wireless communication line by the station;
The exchange station measures the electric field strength of the uplink radio communication line and superimposes and transmits as level data 2 on the downlink radio communication line; and the mobile station transmits the uplink radio data. A digital mobile communication system comprising: a second transmission output control means for analyzing a value of level data superimposed on a communication line to control a transmission output of the base station, wherein the switching center is a downlink wireless communication line. There is a transmission output class information superimposing means for superimposing the transmission output class information of the base station
Then, the first transmission output control means is configured to receive the received downlink wireless call.
Transmission output class information of the base station from the line voice frame
Collect the transmission output class information placed by the superimposing means.
Depending on the value and the measured electric field strength, the base station
Estimate their relative position and send based on the estimation result.
A digital mobile communication system characterized in that the signal output is controlled in multiple stages . 4. An exchange station for accommodating a plurality of base stations to establish a communication connection between mobile stations and between a mobile station and a fixed station, a plurality of base stations accommodated in the exchange station, and a plurality of mobile stations. A mobile terminal, wherein the mobile station measures the electric field strength of the downlink radio communication line, superimposes it as level data 1 on the uplink radio communication line and transmits it, and the exchange. First transmission output control means for controlling the transmission output by analyzing the value of the level data superimposed on the downlink wireless communication line by the station;
The exchange station measures the electric field strength of the uplink radio communication line and superimposes and transmits as level data 2 on the downlink radio communication line; and the mobile station transmits the uplink radio data. In a digital mobile communication system comprising: a second transmission output control unit that analyzes a value of level data superimposed on a communication line and controls a transmission output of the base station, the first transmission output control unit includes: , When the electric field strength of the downlink wireless communication line falls below a certain value during a call, lower the transmission output to the level at which handover is started while monitoring the electric field strength of the uplink wireless communication line notified on the downlink wireless communication line. A digital mobile communication system. 5. An exchange station accommodating a plurality of base stations for establishing a communication connection between mobile stations and between a mobile station and a fixed station, a plurality of base stations accommodated in the exchange station, and a plurality of mobile stations. A mobile terminal, wherein the mobile station measures the electric field strength of the downlink radio communication line, superimposes it as level data 1 on the uplink radio communication line and transmits it, and the exchange. First transmission output control means for controlling the transmission output by analyzing the value of the level data superimposed on the downlink wireless communication line by the station;
The exchange station measures the electric field strength of the uplink radio communication line and superimposes and transmits as level data 2 on the downlink radio communication line; and the mobile station transmits the uplink radio data. In a digital mobile communication system comprising: a second transmission output control means for analyzing a value of level data superimposed on a communication line to control a transmission output of the base station, When the electric field strength is below a certain value and the electric field strength of the uplink radio communication line notified on the downlink radio communication line is sufficiently large, a switching control signal requesting switching of the communication channel within the zone is sent to the exchange. A digital mobile communication system, comprising: a switching control signal transmitting means for transmitting by means of a transmission. 6. An exchange station for accommodating a plurality of base stations to establish a communication connection between mobile stations and between a mobile station and a fixed station, a plurality of base stations accommodated in the exchange station, and a plurality of mobile stations. A mobile terminal, wherein the mobile station measures the electric field strength of the downlink radio communication line, superimposes it as level data 1 on the uplink radio communication line and transmits it, and the exchange. First transmission output control means for controlling the transmission output by analyzing the value of the level data superimposed on the downlink wireless communication line by the station;
The exchange station measures the electric field strength of the uplink radio communication line and superimposes and transmits as level data 2 on the downlink radio communication line; and the mobile station transmits the uplink radio data. In a digital mobile communication system comprising: a second transmission output control means for analyzing a value of level data superimposed on a communication line to control a transmission output of the base station, Digital mobile communication characterized by having a visual notification means for notifying a user when the electric field strength is below a certain value and the electric field strength of the uplink radio communication line notified on the downlink radio communication line is sufficiently large. system. 7. An exchange station for accommodating a plurality of base stations to establish communication connection between mobile stations and between a mobile station and a fixed station, a plurality of base stations accommodated in the exchange station, and a plurality of mobile stations. A mobile terminal, wherein the mobile station measures the electric field strength of the downlink radio communication line, superimposes it as level data 1 on the uplink radio communication line and transmits it, and the exchange. First transmission output control means for controlling the transmission output by analyzing the value of the level data superimposed on the downlink wireless communication line by the station;
The exchange station measures the electric field strength of the uplink radio communication line and superimposes and transmits as level data 2 on the downlink radio communication line; and the mobile station transmits the uplink radio data. In a digital mobile communication system comprising: a second transmission output control means for analyzing a value of level data superimposed on a communication line to control a transmission output of the base station, When the electric field strength is below a certain value and the electric field strength of the uplink radio communication line notified on the downlink radio communication line is sufficiently large, it has a warning means for generating a warning sound to notify the user. And a digital mobile communication system. 8. The mobile station, when the downlink electric field strength is below a certain value during the call, and the electric field strength of the uplink radio communication line notified on the downlink radio communication line is sufficiently large,
Characterized by having a switching request signal transmitting means for transmitting a call channel switching request signal within the zone
The digital mobile communication system according to claim 6 or 7 .