JP4486232B2 - Wireless communication device - Google Patents

Description

[0001]
[Technical field to which the invention belongs]
The present invention relates to a wireless communication apparatus that performs communication using a time division multiple access (TDMA) system, and more particularly to reduction of current consumption during reception of a portable wireless communication apparatus driven by a battery.
[0002]
[Prior art]
A mobile wireless communication device such as a portable wireless device establishes a communication line using radio waves with a wireless base station, and performs communication by transmitting and receiving voice, data, etc. wirelessly. From the viewpoint of frequency utilization efficiency, TDMA Mobile phone systems of the type are widely used. This TDMA wireless communication apparatus operates so as to receive a reception slot assigned to the own apparatus, transmit in a transmission slot assigned to the own apparatus, and repeat transmission / reception intermittently.
[0003]
In addition, since portable wireless communication devices such as mobile phones are driven by batteries, it is necessary to reduce power consumption in order to ensure long-time operation. In the TDMA system, since transmission / reception operations are intermittently performed between the transmission slot and the reception slot, the reception unit operates intermittently only between the reception slots assigned to the own device.
[0004]
An example of the operation timing of the transmission / reception slot and the reception unit is shown in FIG. FIG. 10 is a diagram showing transmission / reception timing of a mobile device in a PDC (Personal Digital Cellular) system which is a digital automobile / mobile phone system adopted in Japan. For example, a downlink signal transmitted from the base station is received by the mobile station in the reception slot (R). Further, an uplink signal is transmitted from the mobile device to the base station in a transmission slot (T). In the figure, I is an idle time during which the mobile device is not performing a transmission / reception operation. In the PDC system, at the timing described above, the mobile device performs transmission / reception operations by repeating three states of transmission, reception, and idle at predetermined time intervals.
[0005]
At this time, the mobile device operates the reception unit so as to receive the downlink signal from the base station in the reception slot assigned to the mobile device. That is, the power of the receiving unit is turned on in the receiving slot (R) to operate the receiving unit, and the power of the receiving unit is shut off in the transmission slot (T) and standby (I) to operate the receiving unit. Has stopped.
[0006]
[Problems to be solved by the invention]
In a conventional TDMA wireless communication device, a receiving unit is operated in a receiving slot assigned to the own device, and all data contained in the receiving slot is received. In particular, the above-described PDC system includes two types of signals (CRC code and BCH code) that can detect whether the control signal transmitted from the base station is error-free, so that the state of the radio channel is good. Even in an environment where the received signal is strong and the electric field strength is high and no error occurs in the received data, both signals (CRC code and BCH code) that can detect data errors are received. It was.
[0007]
In addition, the downlink signal from the base station includes a collision control signal for controlling transmission (random access) from the mobile device so that a plurality of mobile devices do not simultaneously transmit the uplink signal in the same transmission slot. include. This information is not necessary for a mobile station that is not transmitting in the immediately preceding transmission slot.
[0008]
As described above, the conventional TDMA wireless communication device has received all the data included in the reception slot, and even when unnecessary data is included in the reception slot depending on the current state of the own device, Since the reception unit operates to receive even unnecessary data, useless power is consumed, and the use time of the wireless communication device is shortened.
[0009]
The present invention reduces the operating time of the receiving unit (and the oscillating unit) and reduces power consumption by the TDMA wireless communication device judging the current state of its own device and not receiving unnecessary data. An object of the present invention is to provide a wireless communication device that can be used for a long time.
[0010]
[Means for Solving the Problems]
In the first invention, reception slots are repeated at predetermined intervals to receive data intermittently. Have a receiver , Sent in the receiving slot Receive In the data, The Can detect received data errors Error detection signal And an error correction signal capable of correcting an error in the received data. In a wireless communication device that performs communication using the TDMA method, Error detection Receive the signal, Error detection By signal (eg CRC code) Said If no error is detected in the received data, The error correction sent following the error detection signal Avoid receiving at least part of the signal (eg BCH code) And stop the receiving operation of the receiving unit. control The A wireless communication device comprising control means for performing
[0014]
First 2 In the invention, data is transmitted and received by repeating a transmission slot and a reception slot at predetermined intervals. Have a transmitter and receiver And sent in the receiving slot Receive In the data, Said In a wireless communication device that performs communication by a TDMA system including a transmission control signal for controlling transmission in a transmission slot, The wireless communication device But, Said In the transmit slot before and after the receive slot The transmitter is When not sending In Is Included in the receive slot Of the transmission control signal at least Do not receive some And stop the reception operation of the transmitter and receiver. control The It has the control means to do.
[0015]
First 3 In the invention, data is transmitted and received by repeating a transmission slot and a reception slot at predetermined intervals. Have a transmitter and receiver And sent in the receiving slot Receive In the data, The Can detect received data errors Error detection Signal and An error correction signal capable of correcting an error in the received data; and A transmission control signal for controlling transmission in the transmission slot, And, The transmission control signal is located at the end of the reception slot, and the error correction In a wireless communication device that communicates by a TDMA method in which a signal is transmitted before the transmission control signal, Said When not transmitting in the transmission slot before and after the reception slot, do not receive the transmission control signal, and further when not receiving the transmission control signal, Error detection Receive the signal, Error detection If no error in the received data is detected by the signal, The correctable signal sent following the error detection signal Control means for controlling not to receive at least part of the signal is provided. When receiving the transmission control signal, control may be performed so as to receive a signal capable of detecting the second error.
[0022]
In particular, in the first, second and third inventions, it is not necessary to receive a signal capable of detecting the second error unless an error in transmission data is detected by the signal capable of detecting the first error. Since it can be judged, it is configured not to receive all or part of the signal capable of second error detection. Therefore, since the reception operation is stopped without receiving a signal capable of detecting the second error, which is unnecessary in a propagation state where the received electric field strength is strong and no error occurs in the received data, the current consumption of the receiving unit Can be reduced. Further, as in the third invention, the signal capable of detecting the first error is an error detection signal (CRC code), and the signal capable of detecting the second error is longer in data length than the error detection signal. In the case of an error correction signal (BCH code), the amount of received data is reduced, and the effect of reducing power consumption is great.
[0023]
In the fourth and fifth inventions, when the mobile station is not transmitting in the transmission slot immediately before the reception slot, it can be determined that it is not necessary to receive the transmission control signal (collision control signal). Since the reception operation is stopped without receiving all or part of the transmission control signal including information based on the transmission slot, the current consumption is reduced by shortening the operation time of the reception unit. Can do.
[0024]
In the sixth aspect of the invention, when the transmission control signal (collision control signal) is not received, it is determined whether to receive a signal capable of second error detection. When the transmission control signal is located at the end of the reception slot and the signal (BCH code) capable of second error detection is located before the transmission control signal, the reception of the reception slot is interrupted halfway, The reception operation can be stopped without receiving the transmission control signal and the signal capable of detecting the second error, and the current consumption of the receiving unit can be efficiently reduced with simple control.
[0025]
In the seventh invention, the operation of the receiving unit is stopped by shutting off the power supplied to the receiving unit, so that the signal is not received, so the receiving operation is stopped by simple control, Current consumption can be reduced more reliably than other reception operation stopping means.
[0026]
In the eighth aspect of the invention, when the reception of signals unnecessary for the mobile device is stopped, the operation of the oscillating unit is stopped in addition to the receiving unit, so that the operation of only the receiving unit is stopped. Thus, current consumption can be further reduced. In order to stop the operation of the oscillation unit, the power supplied to the oscillation unit may be shut off.
[0027]
In the ninth aspect of the invention, when the transmission is scheduled to be performed in the next transmission slot, the operation of the oscillation unit (particularly, the PLL synthesizer) is not stopped, so the PLL of the oscillation unit involved in the generation of the transmission signal is configured. Even if the synthesizer is turned on and the rise time until the output frequency stabilizes is slow, the operation of the oscillation unit can be stopped without affecting the transmission signal, and the power consumption during reception is reduced. Can do.
[0028]
In the tenth aspect of the invention, since the reception operation of the data is stopped according to the counting result of the number of bits of the reception data, it is easily controlled not to receive the reception data located at the specific number of bits. Can do.
[0029]
DETAILED DESCRIPTION OF THE INVENTION
Next, embodiments of the present invention will be described with reference to the drawings.
[0030]
FIG. 1 is a block diagram showing the overall configuration of the mobile phone according to the present embodiment.
[0031]
The antenna 1 is connected to the transmission unit 2 and the reception unit 3 and receives radio waves (downstream signals) from the radio base station and transmits radio waves (upstream signals) to the radio base station. The transmission unit 2 generates a high frequency signal to be transmitted from the antenna 1. The receiving unit 3 amplifies and frequency-converts the high frequency signal received by the antenna 1 and outputs it to the baseband processing unit 5 as a baseband signal. The oscillation unit 4 includes a PLL synthesizer, a crystal oscillator, and the like. The output frequency is controlled by a signal from the control unit, and a local oscillation frequency signal (local signal) that matches the transmission / reception frequency is generated. This local signal is supplied to the transmission unit 2 and the reception unit 3. The transmission unit 2 multiplies the local signal to generate a high-frequency signal having a predetermined frequency determined with the base station. The receiving unit 3 converts the local signal and the received high-frequency signal into a baseband frequency signal by mixing in the mixer unit. The baseband signal is decoded into a voice signal by the voice encoding / decoding unit 6 and sent to the receiver unit 8. Also, the voice signal input from the transmitter 7 is encoded by the voice encoder / decoder 6 and sent to the baseband processor 5.
[0032]
The control unit 9 controls each unit of the mobile phone such as the transmission unit 2, the reception unit 3, and the oscillation unit 4. The transmission unit 2 controls the transmission frequency and the output of radio waves to be transmitted, and the reception unit 3 controls the reception frequency. In particular, with respect to the receiving unit 3 and the oscillating unit 4, the receiving unit 3 and the oscillating unit 4 are operated according to the timing of the receiving slot in order to operate the receiving unit 3 and the oscillating unit 4 intermittently and to receive intermittently. Controls the power on / off. In addition, character information and display data for displaying the operating state of the mobile phone are sent to the display unit (not shown), and characters and numbers are input from the input unit (not shown) and the operation to the mobile phone is performed. Accept instructions.
[0033]
FIG. 2 is a diagram showing a format of the control signal.
[0034]
The control signal is transmitted from the base station to the mobile station in the reception slot, and includes a broadcast channel (BCCH), a general call channel (PCH) as a common control channel (CCCH), a dedicated cell channel (SCCH), and the like. . This 1-slot control signal is composed of 280 bits, and after a guard time of 4 bits for preventing bursts from colliding with the distance between the mobile station and the base station, a carrier synchronization and clock synchronization preamble (2 bits) ), First 112 bits of information data (CAC) as a control signal, synchronization word (20 bits) for frame synchronization, color code (8 bits) transmitted and received between the mobile station and the base station, and information 112 bits in the second half of the data (CAC), a collision control signal (22 bits) for controlling transmission (random access) from the mobile device so that upstream signals from multiple mobile devices are not sent simultaneously in the same transmission slot ) Is sent. The end of the information data (CAC) includes a 64-bit BCH code which is an error correction signal described later.
[0035]
The collision control signal included at the end of this control signal has a configuration shown in FIG. The first 3 bits are an idle / busy bit (I / B) indicating a result of detecting on the base station side whether an uplink channel (for example, dedicated cell channel SCCH, user packet channel UPCH) is free or blocked. If the upstream channel is free, the transmission permission signal (I) is transmitted, and if the upstream channel is blocked, the transmission prohibition signal (B) is transmitted. If this signal is I, the mobile station can transmit in the next transmission slot, and if it is B, it cannot transmit in the next transmission slot.
[0036]
The next 3 bits indicate whether or not the base station has received an upstream signal from the mobile station. When the base station receives an upstream signal, the base station receives (R). If no upstream signal is received, non-reception (N) is transmitted. Further, the last 16 bits are a partial echo field (PE) returned including the CRC code of the signal included in the upstream channel received by the base station, and the mobile station receives this partial echo field. Thus, it is possible to know whether the base station has correctly received the data transmitted by itself.
[0037]
FIG. 4 is a timing diagram illustrating an operation of the reception unit 3 according to the first embodiment of this invention.
[0038]
In the first embodiment, it is not necessary to transmit an uplink signal from a mobile device, that is, the mobile device does not transmit an uplink signal in the previous transmission slot and transmits in the next transmission slot. When there is no plan to do so, the collision control signal is not received, the supply of power to the receiving unit 3 is interrupted in the middle of the receiving slot, and the receiving operation is stopped. Here, the state in which transmission of an uplink signal from a mobile device is not required is a state in which the mobile device is in a standby state and does not move its position, so there is no need for location registration or handover, and the base station The propagation state between the two signals does not change (the transmission power does not need to change for both the upstream signal and the downstream signal).
[0039]
As described above, the collision control signal includes information regarding the result of the base station receiving the uplink signal transmitted by the mobile device. This information is not necessary when the mobile station is not transmitting an upstream signal in the transmission slot. Further, the collision control signal includes information regarding permission / non-permission of transmission in the next transmission slot. This information is unnecessary when the mobile station does not transmit an upstream signal in the next transmission slot. Thus, a mobile device that does not require transmission does not need to receive a collision control signal.
[0040]
Here, in the PDC system, since the collision control signal is included at the end of the data in the reception slot, when the mobile station does not transmit, the reception of the reception slot is interrupted halfway, and the control signal is received before the collision control signal. End. That is, when the mobile station does not transmit an uplink signal in the immediately preceding transmission slot (T) and does not plan to transmit an uplink signal in the next transmission slot, the latter half of the information data (CAC) is received. Thereafter, the power supply of the receiving unit 3 is shut off without receiving the collision control signal (E), and the receiving operation is stopped.
[0041]
Specifically, the baseband processing unit 5 counts the number of bits received in the receiving slot, and stops the operation of the receiving unit 3 when the number of received bits from the beginning of the receiving slot reaches 258 bits. In addition, a power control signal is sent to the receiving unit 3 and the oscillating unit 4 via the control unit 9. Upon receiving this power control signal, the receiving unit 3 shuts off the power and stops its operation. After that, the baseband processing unit 5 restarts the operation of the receiving unit 3 in accordance with the start of the next receiving slot based on the elapsed time from the reference of the already synchronized frame (for example, at the start of the receiving slot). Then, a power control signal is sent to the receiving unit 3 via the control unit 9 to supply power to the receiving unit 3 and start the operation of the receiving unit 3.
[0042]
At this time, the baseband processing unit 5 counts the elapsed time from the beginning of the reception slot instead of counting the number of reception bits, and takes the time corresponding to 258 bits (about 6.2 milliseconds). It can also be configured to stop the operation.
[0043]
As described above, in the first embodiment, the power supply of the reception unit 3 is cut off. However, in addition to cutting off the power supply of the reception unit 3, the oscillation unit that generates a local signal input to the reception unit 3. The power supply to 4 can be cut off, and the operation of the oscillation unit 4 can also be stopped. However, since the local signal from the oscillating unit 4 is also used to generate a transmission signal in the transmitting unit 2, if the operation of the synthesizer of the oscillating unit 4 is stopped unnecessarily, transmission cannot be performed in a desired transmission slot. Become. That is, in consideration of the rise time from when the oscillation unit 4 is turned on until the output frequency is stabilized, it is better not to stop the oscillation unit 4 when transmission is scheduled in a transmission slot within a time shorter than the rise time. . Therefore, when there is a transmission schedule in a transmission slot within a predetermined time (for example, the next or successive), only the operation of the reception unit 3 is stopped, and the oscillation unit 4 is used for transmission in the next transmission slot. It is good to comprise so that operation | movement may be continued. On the other hand, when there is no transmission plan within a predetermined time (for example, in the next or subsequent transmission slot), control is performed so that the operation of the oscillation unit 4 is stopped in addition to the operation of the reception unit 3.
[0044]
By shutting off the power supply to the oscillating unit 4 in this way, it is possible to further reduce power consumption as compared with the case where the power source of only the receiving unit 3 is shut off.
[0045]
FIG. 5 is a flowchart showing a control channel reception operation according to the first embodiment of the present invention.
[0046]
In the control channel reception process, when reception of a new reception slot is started (step S101), reception is performed up to the end of the information data (CAC) (step S102). Thereafter, the presence / absence of transmission of an upstream signal to the base station in the immediately preceding transmission slot is checked (step S103). If an upstream signal to the base station is not transmitted in the immediately preceding transmission slot (no step S103), it is checked whether or not there is a plan to transmit an upstream signal to the base station in the subsequent transmission slot (step S104). If there is no plan to transmit an uplink signal to the base station in the next transmission slot (No in step S104), the reception of this reception slot is terminated, and the control channel reception process is returned to the beginning, and the next is performed at a predetermined timing. Reception of the receiving slot is started.
[0047]
On the other hand, if an uplink signal to the base station is transmitted in the immediately previous transmission slot (Yes in step S103), or if there is a plan to transmit an uplink signal to the base station in the next transmission slot (step S103). Receiving collision control signal, that is, receiving up to the last data of this reception slot (step S105), returning to the beginning of this control channel reception process, and receiving the next reception slot at a predetermined timing To start.
[0048]
As described above, in the first embodiment, when the mobile device does not require transmission, the reception unit 3 is stopped before receiving the collision control signal. It is not necessary to receive useless data even when transmission is not required, and by shortening the operation time of the receiving unit 3, the power consumption is reduced and the operation time when the mobile device is in standby is lengthened. be able to.
[0049]
In the PDC system, since the collision control signal is included at the end of the reception slot, it is only necessary to stop the reception operation in the middle of the reception slot, and to repeatedly stop / start the reception operation in the middle of the reception slot. There is no need for complicated control, and power consumption can be reduced with simple control.
[0050]
FIG. 6 is a timing diagram illustrating an operation of the reception unit 3 according to the second embodiment of this invention.
[0051]
In the second embodiment, in addition to not receiving the collision control signal described in the first embodiment, the BCH code that is an error correction signal is not received and is received earlier than the first embodiment. Stop receiving slot.
[0052]
FIG. 7 is a diagram illustrating a configuration of information data of the control signal.
[0053]
FIG. 7 shows information data (control data) of reception data composed of 224 bits in 14 bits × 16 rows. This control data includes the first bit of the first row, the first bit of the second row, the first bit of the fifteenth row, the first bit of the sixteenth row, as indicated by an arrow line (dotted line) in the figure. 1st row 2nd bit ... Transmitted in order of 2nd bit of 16th row, 7th bit of 1st row, ... 7th bit of 16th row is transmitted, 112 bits of the first half are transmitted Ends. Then, starting from the 8th bit of the 1st row, the 14th bit of the 16th row is transmitted, and the latter 112 bits are transmitted.
[0054]
Of the control data, 16 bits from the 5th bit to the 10th bit in the 15th row and the 1st bit to the 10th bit in the 16th row are assigned to the CRC code, and the error of the control data received by this code Can be detected. Further, the 11th to 14th bits (1st to 16th lines) of the control data are assigned to the BCH code, and it is possible to determine whether the data is correct and correct for each line. Yes.
[0055]
According to the transmission order described above, the BCH code is transmitted in the last 64 bits of the latter half of the control data. Referring to FIG. 2, the BCH code is located before the collision control signal, and is located 195 to 258 bits from the beginning of the reception slot.
[0056]
Therefore, as shown in FIG. 6, in the second embodiment, if there is no error in the received data as a result of receiving the CRC code, the BCH code and the collision control signal are not received in the middle of the reception slot. The operation of the receiving unit 3 is stopped and the receiving operation is terminated.
[0057]
Specifically, after receiving the CRC code included in the received information data, the baseband processing unit 5 of the mobile device collates the received control signal with the content of the CRC code, and whether the content of both matches. Confirm. When an error of the control signal is detected by the CRC code, if there is one error in one row (1st to 10th bits), the error of the control signal can be corrected by the BCH code. However, when the received electric field is strong and the fluctuation is small, such as the distance between the mobile station and the base station is small, there is no error in the received control data. If this is confirmed, the BCH code for error correction is not used, so there is no need to receive the BCH code. Therefore, the baseband processing unit 5 sends a power control signal from the control unit 9 to the receiving unit 3 so as to stop the receiving operation. Receiving unit 3 that has received this power control signal shuts off the power and pauses the receiving operation. Thereafter, the baseband processing unit 5 measures the elapsed time from the reference time of the already synchronized frame (for example, at the start of the reception slot), and resumes the operation of the reception unit 3 at the start of the next reception slot. As described above, the control unit 9 sends a power control signal to the receiving unit 3 to supply power to the receiving unit 3, and starts the operation of the receiving unit 3.
[0058]
Further, as described above in the first embodiment, the operation of the oscillation unit 4 that generates the local signal can also be stopped. Further, the power supply of the oscillation unit 4 can be controlled to be switched between operation / stop depending on the transmission schedule in the subsequent transmission slot.
[0059]
FIG. 8 is a flowchart showing a control channel reception operation according to the second embodiment of the present invention.
[0060]
In the control channel reception process, when reception of a new reception slot is started (step S111), an error detection signal (CRC code) is received (step S112). Thereafter, whether or not an upstream signal is transmitted to the base station in the immediately preceding transmission slot is checked (step S113). If the upstream signal to the base station is not transmitted in the immediately preceding transmission slot (no step S113), the baseband processing unit 5 compares the received control signal with the CRC code to detect an error in the control signal. (Step S114). If an error is detected by this error detection (CRC check) (NG in step S114), an error correction signal (BCH code) is received and the control signal error is corrected by the BCH code (step S115). ). Thereafter, the control channel reception process is returned to the beginning, and reception of the next reception slot is started at a predetermined timing in preparation for reception of the next reception slot.
[0061]
On the other hand, when the baseband processing unit 5 collates the control signal with the CRC code and determines that there is no error in the control data (OK in step S114), this error correction signal (BCH code) is received without receiving this error. Returning to the beginning of the control channel reception process, reception of the next reception slot is started at a predetermined timing.
[0062]
Further, in step S113, if an uplink signal to the base station is transmitted in the transmission slot immediately before this reception slot, or if there is a transmission plan in the next transmission slot (Yes in step S113), Following the error detection signal (step S112), an error correction signal is received (step S116), and a collision control signal is received (step S117). During this period, control data reception errors are corrected as necessary. Thereafter, the process returns to the beginning of the control channel reception process, and reception of the next reception slot is started at a predetermined timing.
[0063]
In the first and second embodiments, the method of shutting down the power supply of the receiver 3 has been described as the method of stopping the operation of the receiver 3, but the effect of reducing the current consumption is inferior, The method of stopping the supply of the local signal to the unit 3 or the input of the receiving unit 3 is cut off, so that the receiving unit 3 is brought into the non-input state, and the operation of the receiving unit 3 is substantially stopped to reduce the power consumption. It can also be reduced.
[0064]
As described above, in the second embodiment, it is determined whether an error correction signal (BCH code) is received based on the result of error detection using the error detection signal after receiving up to the error detection signal (CRC code). When no error is detected, the receiving unit 3 is stopped so that an error correction signal is not received. Further, the collision control signal is not received when transmission is not performed in the previous transmission slot. Therefore, it is not necessary to receive useless data (BCH code) when the mobile device is in a stable reception state where the reception electric field is strong and does not fluctuate, such as during standby. In addition, since it is not necessary to receive useless data (collision control signal) in a state where transmission is not required, the power consumption can be reduced by shortening the operation time of the receiving unit 3, and wireless operation that operates on a battery. The operating time of the communication device can be lengthened.
[0065]
Also, since the BCH code is located before the collision control signal located at the end of the control signal, when the above-described collision control signal is not received, after receiving the CRC code, the BCH code is not received until the end. By ending the reception of data in the reception slot, it is not necessary to perform complicated control to repeatedly stop / start the reception operation in the middle of the reception slot, and power consumption can be reduced with simple control.
[0066]
FIG. 9 is a flowchart illustrating a control channel reception operation according to the third embodiment of the present invention.
[0067]
In this embodiment, as in the second embodiment described above, the error correction signal (BCH code) and the collision control signal (E) are not received depending on the state of the mobile station. The operation is performed at the timing shown in FIG. In the present embodiment, the reception operation is continued during an error check using a CRC code that is an error detection signal, the operation of the reception unit 3 is stopped according to the CRC check result, and the oscillation unit is further transmitted according to a transmission schedule in a later transmission slot. 4 is also characterized by stopping. That is, the content of the control signal received by the mobile device is checked based on the reception result of the CRC code, and when the determination is completed and the content matches, the power of the receiving unit 3 is turned off to stop receiving the BCH code. Cut off.
[0068]
In this control channel reception process, power is supplied to the PLL synthesizer of the oscillating unit 4, the PLL synthesizer is operated, and output of the local oscillation frequency from the oscillating unit 4 is started (restarted) (step S121). Thereafter, power is supplied to the receiver 3 to operate the receiver 3 (step S122), reception of a new control channel is started (step S123), and control data up to the error correction signal (CRC code) is received. Receive (step S124). Thereafter, the presence / absence of transmission of an upstream signal to the base station in the immediately preceding / immediate transmission slot is checked (step S125). If the uplink signal to the base station is not transmitted in the immediately preceding transmission slot and there is no transmission schedule in the next transmission slot (no step S125), the baseband processing unit 5 receives the received control data and CRC. The code is checked to determine whether there is an error in the control signal (step S126). In the third embodiment, the BCH code transmitted after the CRC code is continuously received even during the error detection determination (CRC check) by the CRC code. If an error is detected by this CRC check (NG in step S126), an error correction signal (BCH code) is subsequently received, error correction is performed, and a control signal reception error is corrected (step S127). The reception of the reception slot is terminated.
[0069]
On the other hand, when the baseband processing unit 5 collates the control signal with the CRC code and determines that there is no error in the control signal (OK in step S126), reception of the error correction signal is interrupted and reception of the reception slot is performed. Exit.
[0070]
If an uplink signal to the base station is transmitted in the immediately preceding transmission slot (Yes in step S125), an error detection signal is received (step S131), and then a collision control signal is received (step S132). . During this time, if necessary, the control data reception error is corrected and reception of the reception slot is terminated.
[0071]
When the reception slot is received up to a signal (symbol) determined by the state of these mobile devices, the baseband processing unit 5 sends a power control signal to the reception unit 3 so as to shut off the power supply of the reception unit 3, The power supply of the receiving part 3 is interrupted | blocked and reception operation | movement is stopped (step S128).
[0072]
Further, the control unit 9 determines whether or not there is a transmission plan in a transmission slot within a predetermined time determined by the rise time of the oscillation unit 4 described above (step S129). If there is no transmission plan, the power source of the oscillation unit 4 is also shut off. Then, the operation of the oscillation unit 4 is stopped. Thereafter, the control channel reception process is returned to the beginning, and in preparation for reception of the next reception slot, the oscillation unit 4 and the reception unit 3 are turned on at a predetermined timing to resume the reception operation (steps S121 and S122). Then, reception of the next reception slot is started (step S123).
[0073]
On the other hand, if there is a transmission schedule in a transmission slot within a predetermined time (existing in step S129), the control channel reception is performed while maintaining the transmission output from the oscillation unit 4 without shutting off the power supply of the oscillation unit 4. Returning to the beginning of the process, in preparation for the reception of the next reception slot, the oscillation unit 4 and the reception unit 3 are turned on at a predetermined timing to restart the reception operation (steps S121 and S122). Reception is started (step S123).
[0074]
Thus, in the third embodiment, the power supply of the receiving unit 3 is shut off after it is determined that the error detection check result is good. That is, after receiving the error detection signal, the receiver 3 is continuously operated to receive the error correction signal transmitted following the error detection signal, and when it is determined that the error correction signal is unnecessary. The operation of the receiving unit 3 is stopped. Therefore, when it takes time to determine error detection and it is determined that there is an error in the received data, even if the error correction signal has already started, all of the error correction signal is received without being lost. can do. Since it is not necessary to receive useless data depending on the state of the own device, it is possible to reduce the power consumption by shortening the operation time of the receiving unit 3, and the operation time of the wireless communication device operated by the battery Can be lengthened.
[0075]
Further, since the power supply of the oscillation unit 4 in addition to the reception unit 3 is shut off and the operation is stopped, the current consumption can be further reduced.
[Brief description of the drawings]
FIG. 1 is a block diagram of a mobile phone according to an embodiment of the present invention.
FIG. 2 is a diagram illustrating a format of a control signal.
FIG. 3 is a diagram illustrating a format of a collision control signal.
FIG. 4 is a timing diagram illustrating an operation of the reception unit according to the first embodiment of this invention.
FIG. 5 is a flowchart showing the operation of the first exemplary embodiment of the present invention.
FIG. 6 is a timing diagram illustrating an operation of a reception unit according to the second embodiment of this invention.
FIG. 7 is a diagram illustrating a data structure of a control signal.
FIG. 8 is a flowchart showing the operation of the second exemplary embodiment of the present invention.
FIG. 9 is a flowchart showing the operation of the third exemplary embodiment of the present invention.
FIG. 10 is a timing diagram showing an operation of a conventional receiving unit.
[Explanation of symbols]
1 Antenna (ANT)
2 Transmitter (TX)
3 Receiver (RX)
4 Oscillator (LO)
5 Baseband processing part (B / B)
6 Speech coding / decoding unit (CODEC)
7 Speaker (MIC)
8 Receiver (REC)
9 Control unit (CONT)

Claims (3)

A receiving unit that receives data intermittently by repeating reception slots at predetermined intervals,
To receive data transmitted by the receiving slot, the radio communication device to a detectable error detection signal an error in the received data, the communication by TDMA system which includes a correctable error correction signal errors in the received data In
Receiving said error detection signal, if error is detected in said received data by said error Ri detection signal, so as not to at least a part of the reception of the error correction signal transmitted subsequent to said error Ri detection signal with a wireless communication device, characterized in that it comprises a control means for controlling to stop the reception operation of the reception unit.   The transmission slot and the reception slot have a transmission section and a reception section that transmit and receive data by being repeated at predetermined intervals,
  In a wireless communication apparatus that performs communication by a TDMA system including a transmission control signal for controlling transmission in the transmission slot in reception data transmitted in the reception slot,
  When the wireless communication device is not transmitting in the transmission slot before and after the reception slot, the wireless communication device is configured not to receive at least a part of the transmission control signal included in the reception slot, and A wireless communication device comprising control means for controlling to stop the reception operation of a transmission unit and a reception unit.   The transmission slot and the reception slot have a transmission section and a reception section that transmit and receive data by being repeated at predetermined intervals,
  In order to control transmission in the transmission slot, an error detection signal capable of detecting an error in the reception data, an error correction signal capable of correcting an error in the reception data, and reception data transmitted in the reception slot Wireless communication in which communication is performed by a TDMA system in which the transmission control signal is located at the end of the reception slot and the error correction signal is located before the transmission control signal. In the machine
  When transmission is not performed in transmission slots before and after the reception slot, the transmission control signal is not received. Further, when the transmission control signal is not received, the error detection signal is received, and the error detection signal is received. And a control means for controlling not to receive at least a part of the correctable signal transmitted subsequent to the error detection signal if no error is detected in the received data. .

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