JP2001292090A - Mobile phone and semiconductor device for the mobile phone - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a mobile phone and a semiconductor device for the mobile phone that can suppress increase in the memory capacity, reduce the power consumption and eliminate the deterioration in the system performance. SOLUTION: A received data storage memory 6 is shared for storing received data and transmission data so as to eliminate the need for classifying data into received voice data, received control data, transmission voice data, and transmission control data thereby reducing the memory capacity, and since the received data storage memory 6 does not discriminate the received data from the transmitted data so that the stored received data are transmitted as they are, the copy processing of data by a CPU 10 or the like is avoided for data relaying, the power consumption for data copy processing is reduced and the occupied period of a CPU bus 14 by the data copy processing is eliminated.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a portable telephone and a semiconductor device for a portable telephone for transmitting and receiving information through radio waves for communication.

[0002]

2. Description of the Related Art In recent years, a portable telephone system using a portable telephone device which communicates by transmitting and receiving information through radio waves has been developed at an extremely high speed. A mobile phone is generally configured to process received data and transmission data as communication information via a memory so that information can be communicated using the processed data.

[0003] The conventional portable telephone as described above will be described below. FIG. 3 is a block diagram showing a configuration of a conventional mobile phone. Here, a digital mobile phone for transmitting and receiving signals in a digital format for communication will be described as an example. 3, 1 is an antenna, 2 is a demodulation unit, 3 is a reception data processing unit, 4 is a modulation unit, 5 is a transmission data processing unit,
10 is a CPU, 11 is an audio codec, 12 is a speaker, 13 is a microphone, 14 is a CPU bus, and 15 is a direct memory access (DMA) for reading and writing to and from a memory.
A DMA controller controlled by the system, 16 is a memory for storing reception control data, 17 is a memory for storing reception voice data, 18 is a memory for storing transmission voice data, and 19 is a memory for storing transmission control data.

A memory 16 for storing reception control data, a memory 17 for storing reception audio data, a memory 18 for storing transmission audio data, and a memory 19 for storing transmission control data each have one port as a write port and one port as a read port. And a dual-port memory having two ports.

[0005] The operation of the digital portable telephone configured as described above will be described below. In a normal digital mobile phone, a signal received by the antenna 1 is demodulated by the demodulation unit 2 and input to the reception data processing unit 3. The reception data processing unit 3 performs a restoration process on the reception data to restore the control data and the audio data.
The received data thus restored is stored in the received data storage memory, and the received data storage memory has one port as a write port and one port as a read port.
Since this is a dual-port memory having a port, audio data and control data cannot be read at the same time. Therefore, it is necessary to store audio data and control data separately according to the circuit to be read.

Therefore, the audio data of the restored received data is stored in the received audio data storage memory 17,
The voice data and control data are stored in the reception control data storage memory 16.

The received control data stored in this manner is transferred from the received control data storage memory 16 to the CPU bus 1.
4 to the CPU 10 for processing. On the other hand, the received voice data is sent from the received voice data storage memory 17 to the voice codec 11 and reproduced and output from the speaker 12 as an analog voice signal.

In transmitting data, since the transmission data storage memory is a dual port memory having one port as a write port and one port as a read port, it is necessary to simultaneously write transmission voice data and transmission control data. Therefore, it is necessary to separately store the transmission voice data and the transmission control data.

The transmission voice data is stored in the transmission voice data storage memory 18 after the voice from the user is captured by the microphone 13 and converted into a digital signal by the voice codec 11. The transmission control data is transmitted to the CPU 1
0 is stored in the transmission control data storage memory 19 through the CPU bus 14.

The transmission voice data and the transmission control data are read from the transmission voice data storage memory 18 and the transmission control data storage memory 19, and then sent to the transmission data processing unit 5, where the processing for the transmission data is performed. Done. The transmission data processed by the transmission data processing unit 5 is
The signal is modulated by the modulator 4 and transmitted from the antenna 1.

[0011] Further, the digital mobile phone as described above is
When the received data is used as it is for data relay for transmission, the received voice data and control data are transmitted to other digital mobile phones as they are, so that the voice codec 11, the speaker 12, and the microphone 13 In a state where the operation is stopped, the CPU 10 or the DMA controller 15 copies the data as the transmission data from the reception control data storage memory 16 to the transmission control data storage memory 19 through the CPU bus 14.

The copied transmission data is read out from the transmission control data storage memory 19 and sent to the transmission data processing unit 5.
, And thereafter transmitted from the antenna 1 through the same route as a normal mobile phone.

[0013]

However, in the above-mentioned conventional mobile phone, the memory for storing the received data is
Since it is constituted by a dual-port memory having one port as a write port and one port as a read port, the audio codec 11 cannot read the reception audio data at the same time as the CPU 10 reads the reception control data. Separating audio data and control data,
Each must be stored in a dedicated storage memory.

Therefore, the reception control data storage memory 1
6 and the memory 17 for storing received voice data, two memories are required, and the memory capacity required for storing the received data increases. Similarly, for the transmission data, the transmission control data is written by the CPU 10. At the same time, the audio codec 11 cannot write the transmission audio data,
Two memories, the transmission control data storage memory 19 and the transmission voice data storage memory 18, are required, and the memory capacity is increased.

Further, in the case where the above digital portable telephone is used for data relay, in addition to the above-mentioned problems, the reception data storage memory 16 and the reception voice data storage memory 17 transmit data processing. Since the unit 5 cannot read the transmission data, the copying of the voice data and the control data from the reception control data storage memory 16 to the transmission control data storage memory 19 is performed by the CPU.
10 or the DMA controller 15, the power consumption as a whole increases, and the frequency of data copying is high.
There has also been a problem that the time that the U bus 14 is occupied is lengthened and system performance is reduced.

SUMMARY OF THE INVENTION The present invention solves the above-mentioned conventional problems, and suppresses an increase in memory capacity, reduces power consumption, and eliminates a decrease in system performance. A semiconductor device for a telephone is provided.

[0017]

In order to solve the above-mentioned problems, a portable telephone and a semiconductor device for a portable telephone according to the present invention are provided.
By sharing the memory for storing the reception data and the transmission data, it is not necessary to separate the reception voice data and the reception control data and the transmission voice data and the transmission control data and store them in the dedicated memory as in the related art. The memory capacity can be reduced, and in the transmission / reception data storage memory, the distinction between the received data and the transmitted data is eliminated, so the stored received data can be transmitted as it is. In addition, the data copying process by the CPU or the DMA controller is eliminated, the power consumption at the time of the data copying process is reduced, and the occupation period of the CPU bus for each execution of various processes is reduced by eliminating the occupation period of the CPU bus by the data copying process. It is characterized by averaging as a whole.

As described above, an increase in memory capacity can be suppressed, power consumption can be reduced, and a decrease in system performance can be prevented.

[0019]

DESCRIPTION OF THE PREFERRED EMBODIMENTS A portable telephone according to a first aspect of the present invention transmits and receives information through radio waves, processes received data and transmitted data through a memory, and uses the processed data to process the information. A mobile phone that performs communication of the above, further comprising a memory for storing transmission / reception data in which a memory for storing the reception data and the transmission data is shared, and wherein the memory for storing transmission / reception data is arbitrary from other circuits for data processing. Is configured to be readable and writable.

According to a second aspect of the present invention, the memory for storing transmission / reception data according to the first aspect comprises a multi-port memory having a plurality of read and write ports. The mobile phone semiconductor device according to claim 3, wherein the mobile phone transmits and receives information through radio waves, processes the received data and the transmitted data through a memory, and communicates the information using the processed data. A semiconductor device for a mobile phone to be used, comprising: a memory for storing transmission / reception data in which a memory for storing the reception data and transmission data is shared; and a memory for storing the transmission / reception data, the other circuit for processing the data. It is configured to be arbitrarily readable and writable from.

According to a fourth aspect of the present invention, there is provided a semiconductor device for a cellular phone, wherein the memory for storing transmission / reception data according to the third aspect comprises a multi-port memory having a plurality of read and write ports.

According to these configurations, the memory for storing the reception data and the transmission data is shared, so that the reception voice data and the reception control data, and the transmission voice data and the transmission control data are divided into dedicated memories as in the related art. The need to store the received data is eliminated, and the memory capacity can be reduced as a whole, and the received data and transmitted data are no longer distinguished in the transmitted / received data storage memory, so the stored received data can be transmitted as it is Therefore, when used for data relaying, the data copying process by the CPU or the DMA controller is eliminated, the power consumption during this data copying process is reduced, and the CPU bus occupation period due to the data copying process is eliminated. Allows averaging of CPU bus occupation period for each execution That.

Hereinafter, a mobile phone and a semiconductor device for a mobile phone according to an embodiment of the present invention will be specifically described with reference to the drawings. (Embodiment 1) A mobile phone will be described as Embodiment 1 of the present invention.

FIG. 1 is a block diagram showing the configuration of the mobile phone according to the first embodiment. Here, a digital mobile phone for transmitting and receiving signals in a digital format for communication will be described as an example. In FIG. 1, 1 is an antenna, 2 is a demodulation unit, 3 is a reception data processing unit, 4 is a modulation unit, 5 is a transmission data processing unit, 10 is a CPU, 11 is a voice codec, 12
Is a speaker, 13 is a microphone, 14 is a CPU bus,
These are the same as before.

Reference numeral 6 denotes a transmission / reception data storage memory, 7 denotes a reception data storage area secured in the transmission / reception data storage memory 6, 8 denotes a transmission data storage area similarly reserved in the transmission / reception data storage memory 6, Reference numeral 9 denotes a transmission / reception data storage area similarly secured in the transmission / reception data storage memory 6. The transmission / reception data storage memory 6 is a multi-port memory having a plurality of write / read ports.
The receiving data processing unit 3 and the transmitting data processing unit 5, the audio codec 11, and the CPU bus 14 can be arbitrarily read and written.

The operation of the digital portable telephone configured as described above will be described below. As shown in FIG. 1, in the digital mobile phone according to the first embodiment, a high-frequency signal (for example, a radio wave having communication information formatted in a digital format) received by an antenna 1 is demodulated by a demodulation unit 2 and received. The data is input to the data processing unit 3. The reception data processing unit 3 performs a restoration process on the reception data corresponding to the digital communication information, and restores the control data and the audio data included in the communication information. The restored control data and audio data are stored in the reception data storage area 7 secured in the transmission / reception data storage memory 6.
Is stored in

The control data of the received data stored in the received data storage area 7 is transmitted through the CPU bus 14 through the C bus.
The data is read by the PU 10 and processed in the same manner as in the related art. On the other hand, of the received data stored in the received data storage area 7, the audio data is read from a read port different from the read port connected to the CPU bus, and then the audio data is read without passing through the CPU bus 14. It is sent directly to the codec 11 and converted into a speaker 12 as an analog audio signal.
Played from.

At the time of transmission, the audio signal captured by the microphone 13 is converted by the audio codec 11 into audio data which is a digital signal, and the transmission data storage area secured in the transmission / reception data storage memory 6 is stored. Is stored in the storage area 8. The control data is also generated by the CPU 10 and stored in the transmission data storage area 8 via the CPU bus 14 from a write port different from the write port connected to the audio codec.

The transmission data composed of the voice data and the control data is read out from the transmission data storage area 8 and sent to the transmission data processing section 5 where the transmission data processing is performed. The transmission data processed by the transmission data processing unit 5 is modulated by the modulation unit 4 and transmitted from the antenna 1 in the form of a radio wave as communication information having the transmission data.

As described above, in the digital portable telephone according to the first embodiment, at the time of reception, the reception data stored in the reception data storage area 7 is transmitted to the CPU 10 and the audio codec 1.
Since they can be read out simultaneously from one, there is no need to separate control data into audio data and store it as in the past,
The memory capacity required for storing received data can be reduced to half.

Similarly, at the time of transmission, the writing of control data by the CPU 10 and the writing of audio data by the audio codec 11 can be simultaneously performed in the transmission data storage area 8, so that the control data is stored in the transmission data storage area 8 as in the prior art. It is not necessary to store data separately, and the memory capacity required for storing transmission data can be reduced to half.

When the digital mobile phone is used as a data relay for transmitting received data as it is, the reception data storage area 7 and the transmission data storage area 8 are equivalent. Since the received data can be stored in the transmission / reception data storage area 9 and the received data can be read out from the transmission / reception data storage area 9 as transmission data, there is no need to copy the data by the CPU or the DMA controller as in the related art. It is possible to reduce power consumption and prevent a decrease in system performance due to occupation of the CPU bus.

Also in this case, the received data stored is
After being read from the transmission / reception data storage area 9 as transmission data, the data is sent to the transmission data processing unit 5, where the data is processed.
After the modulation, the signal is transmitted from the antenna 1.

In the embodiment shown in FIG. 1, the reading of the received data and the writing of the transmitted data are performed by the CPU.
Although the configuration is performed by the bus 14 and the audio codec 11, the output of the reception data to the external terminal and the input of the transmission data from the external terminal, the reading to the circuit block other than the audio codec, and the circuit block other than the audio codec It is also possible to write data from (Embodiment 2) As Embodiment 2 of the present invention, a semiconductor device for a mobile phone used in the digital mobile phone described as an example in Embodiment 1 will be described.

FIG. 2 is a block diagram showing the configuration of the semiconductor device for a mobile phone according to the second embodiment. In FIG. 2, 2
Is a demodulation unit, 3 is a reception data processing unit, 4 is a modulation unit, 5 is a transmission data processing unit, 10 is a CPU, 11 is an audio codec, and 14 is a CPU bus, which are the same as in the conventional example.

Reference numeral 6 denotes a transmission / reception data storage memory, 7 denotes a reception data storage area secured in the transmission / reception data storage memory 6, 8 denotes a transmission data storage area similarly reserved in the transmission / reception data storage memory 6, Reference numeral 9 denotes a transmission / reception data storage area similarly secured in the transmission / reception data storage memory 6. The transmission / reception data storage memory 6 is a multi-port memory having a plurality of write / read ports.
The receiving data processing unit 3 and the transmitting data processing unit 5, the audio codec 11, and the CPU bus 14 can be arbitrarily read and written.

The operation of the semiconductor device for a digital portable telephone configured as described above will be described below. First, as processing for a received signal, the received data, which is a digital received signal demodulated by the demodulation unit 2, is subjected to a restoration process by the reception data processing unit 3, and the restored reception control data and received speech data are Are stored in the reception data storage area 7 in the transmission / reception data storage memory 6.

The reception control data stored in the reception data storage area 7 in this manner is read out by the CPU 10 through the CPU bus 14, and the reception voice data stored in the reception data storage area 7 is Bus 1
The signal is directly sent to the audio codec 11 without passing through the audio codec 4.

On the other hand, as processing for the transmission signal, transmission audio data which is a digital signal converted by the audio codec 11 and transmission control data generated by the CPU 10 are transmitted without passing through the CPU bus 14. The transmission control data is directly stored in the transmission data storage area 8 in the transmission and reception data storage memory 6 via the CPU bus 14.

The transmission data composed of the transmission voice data and the transmission control data is read out from the transmission data storage area 8 and sent to the transmission data processing section 5, where the transmission data processing is performed. The transmission data processed by the transmission data processing unit 5 is modulated by the modulation unit 4.

As described above, in the semiconductor device for a digital portable telephone according to the second embodiment, the reception data stored in the reception data storage area 7 can be read out simultaneously from the CPU 10 and the audio codec 11 at the time of reception. ,
It is not necessary to store control data in the form of voice data as in the prior art, and the memory capacity required for storing received data is reduced by 1 /
2 can be reduced.

Similarly, at the time of transmission, the writing of control data by the CPU 10 and the writing of audio data by the audio codec 11 can be simultaneously performed in the transmission data storage area 8, so that the control data is stored It is not necessary to store data separately, and the memory capacity required for storing transmission data can be reduced to half.

When the above-described semiconductor device for a digital cellular phone is used as a data relay for transmitting received data as it is, the reception data storage area 7 and the transmission data storage area 8 are equivalent. The received data is stored in the transmission / reception data storage area 9 and the reception data can be read out from the transmission / reception data storage area 9 as transmission data.
There is no need to copy data with the A controller,
It is possible to reduce power consumption and prevent a decrease in system performance due to occupation of the CPU bus.

Also in this case, the received data stored is
After being read from the transmission / reception data storage area 9 as transmission data, the transmission data processing unit 5 and the modulation unit 4 process and modulate the data.

[0045]

As described above, according to the present invention, by sharing the memory for storing the received data and the transmitted data, the received voice data and the received control data and the transmitted voice data and the transmitted control data can be shared as in the prior art. It is no longer necessary to store the received data separately in dedicated memory, and it is possible to reduce the memory capacity as a whole, and in the transmission / reception data storage memory, there is no distinction between received data and transmitted data. It is possible to transmit as it is, and when it is used for data relay, C
Eliminates the data copying process by the PU or DMA controller, reduces the power consumption during this data copying process, and eliminates the CPU bus occupying period due to the data copying process, thereby reducing the CPU bus occupying period for each process execution. Can be averaged.

Therefore, an increase in memory capacity can be suppressed, power consumption can be reduced, and a decrease in system performance can be prevented.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a configuration of a mobile phone according to a first embodiment of the present invention.

FIG. 2 is a block diagram illustrating a configuration of a semiconductor device for a mobile phone according to a second embodiment of the present invention;

FIG. 3 is a block diagram showing a configuration of a conventional mobile phone.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 antenna 2 demodulation unit 3 reception data processing unit 4 modulation unit 5 transmission data processing unit 6 transmission / reception data storage memory 7 reception data storage area 8 transmission data storage area 9 transmission / reception data storage area 10 CPU 11 voice codec 12 speaker 13 Microphone 15 DMA controller 16 Reception control data storage memory 17 Reception audio data storage memory 18 Transmission audio data storage memory 19 Transmission control data storage memory

Claims (4)

[Claims] 1. A mobile phone which transmits and receives information via radio waves, processes received data and transmitted data via a memory, and communicates the information using the processed data. A mobile phone comprising a transmission / reception data storage memory sharing a data storage memory, wherein the transmission / reception data storage memory is arbitrarily readable and writable by another circuit for data processing. . 2. The mobile phone according to claim 1, wherein the transmission / reception data storage memory is constituted by a multi-port memory having a plurality of read and write ports. 3. A semiconductor device for a mobile phone used for a mobile phone that transmits and receives information via radio waves, processes received data and transmitted data via a memory, and communicates the information using the processed data. A transmission / reception data storage memory sharing the reception data and transmission data storage memory, and enabling the transmission / reception data storage memory to be arbitrarily readable and writable from another data processing circuit. A semiconductor device for a mobile phone, comprising: 4. The semiconductor device for a mobile phone according to claim 3, wherein the transmission / reception data storage memory comprises a multi-port memory having a plurality of read and write ports.