KR20040106777A - Device and the Method for sharing the sound data of mobile phone with a couples of modem - Google Patents

Abstract

PURPOSE: A device for sharing sound data of a terminal having a plurality of modems, and a method therefor are provided to process sound data to be shared by modem chips different in format, thereby efficiently using system resources. CONSTITUTION: An AMR(Adaptive Multi-Rate) vocoder(220) receives an analog speaker signal output from a speaker output end of a synchronous EVRC(Enhanced Variable Rate Codec) vocoder(210) of a terminal through a microphone input end. The EVRC vocoder(210) receives an analog speaker signal output from a speaker output end of the AMR vocoder(220) through a microphone input end. An ADPCM(Adaptive Differential Pulse Code Modulation) vocoder(230) processes sound data of the AMR vocoder(220) and the EVRC vocoder(210).

Description

Device and apparatus for sharing sound data of a terminal having a plurality of modems {Device and the Method for sharing the sound data of mobile phone with a couples of modem}

The present invention relates to an apparatus and method for sharing sound data in a mobile communication terminal having a plurality of modems, and more particularly to a DBDM terminal equipped with a synchronous CDMA modem chip and an asynchronous WCDMA modem chip. The present invention relates to a sound data sharing apparatus for a terminal having a plurality of modems and a method for sharing sound data in use in a modem chip.

Conventionally, in a CDMA terminal modem, voice processing converts input sound data into Qualcomm Code Excited Linear Predictive (QCELP) data and then transmits the converted QCELP data to a TSB (Transcoder And Selector Bank) of a control station via a base station. Here, the QCELP data is voice packet data.

In addition to the QCELP data, the voice packet data may also use Enhanced Variale Rate Codec (EVRC) data.

EVRC is a method of encoding speech information variably according to the amount of information of speech. In the silent section where a caller does not speak, speech encoding is performed at a low rate of information, and if the information volume is large, encoding is performed at high speed.

Therefore, it is more efficient than the previous method of always encoding at a constant speed.

This increases the system capacity of a code division multiple access (CDMA) mobile communication system and at the same time saves power consumption.

In a WCDMA terminal modem, when a voice frame is transmitted using a conventional UMTS adaptive multi rate (AMR) codec, a 40-byte header is inserted into a transmission frame to transmit 30 bytes of the voice frame.

If the AMR codec is used and the voice frame is 15-32 bytes, a header of 12 bytes of RTP, 8 bytes of UDP, 20 bytes of IP header, and 40 bytes in total is added above the voice frame.

In the case of AMR, different codec modes may be provided in the uplink and downlink directions, and the codec information may be used to select appropriate air interface protocol modes, including the appropriate channel coding scheme for voice traffic. .

As described above, a problem arises in that two modem chips separately process sound data and thus do not share with each other, resulting in double waste of system resources.

Accordingly, the present invention has been proposed to solve the above-mentioned problems. The DBDM terminal equipped with a synchronous CDMA modem chip and an asynchronous WCDMA modem chip simultaneously uses sound data in use by modem chips having different formats. It is an object of the present invention to provide an apparatus and method for sharing sound data of a terminal having a plurality of modems to be shared by a modem chip.

In order to achieve the above object, the present invention provides a sound data sharing apparatus of a terminal having a plurality of modem processors, the microphone input of the analog speaker signal output from the speaker output terminal of the synchronous EVRC vocoder of the terminal as an analog signal through the microphone input terminal; An ARC vocoder, an EVRC vocoder that receives an analog speaker signal output from the speaker output terminal of the asynchronous AMR vocoder of the terminal as an analog signal through a microphone input terminal, and an ADPCM for processing and storing sound data of the AMR vocoder and the EVRC vocoder It includes a vocoder.

The present invention provides a sound data sharing apparatus for a terminal having a plurality of modem processors, comprising: an EVRC vocoder operable to process EVRC format sound data in a synchronous CDMA mode of the terminal; and an AMR format sound in an asynchronous WCDMA mode of the terminal. An AMR vocoder operable to process data, a format converter for converting different sound data formats of the EVRC vocoder and the AMR vocoder into the same sound data format, and sound data of an EVRC format input through an output end of the format converter Includes an ADPCM vocoder storing in the EVRC region and sound data in the AMR format in the AMR region.

Synchronous sound data stored in the EVRC region of the ADPCM vocoder is converted into AMR format sound data by a format converter, and then input to the AMR vocoder, and processed as asynchronous sound data, and stored in the AMR region of the ADPCM vocoder. The asynchronous sound data is converted into sound data in the EVRC format by the format converter, and then input to the EVRC vocoder and processed as synchronous sound data.

According to an aspect of the present invention, there is provided a method of sharing sound data of a terminal having a plurality of modem processors, the method comprising: determining whether an operation mode is performed by a synchronous CDMA modem processor or an asynchronous WCDMA modem processor when an operation of the terminal starts; And if the current terminal operation mode is an operation mode by a synchronous CDMA modem processor, converting the synchronous sound data into asynchronous sound data and storing the same in the ADPCM vocoder, and as a result of the determination, the current terminal operation mode is asynchronous. If the operation mode by the WCDMA modem processor of the method comprises converting the asynchronous sound data to the synchronous sound data and then storing in the ADPCM vocoder.

The conversion of the synchronous / asynchronous sound data into asynchronous / synchronous sound data uses analog conversion or digital conversion, and the conversion of the synchronous sound data into asynchronous sound data is analog output from the speaker output terminal of the synchronous EVRC vocoder of the terminal. The speaker signal is converted into an analog signal through the microphone input terminal of the AMR vocoder, and the microphone is converted to the synchronous sound data. It converts the microphone input into an analog signal through the microphone input terminal of.

The digital conversion of the synchronous sound data into the asynchronous sound data converts the digital sound data format of the EVRC vocoder into the sound data format of the AMR vocoder in a format converter, and the digital conversion of the asynchronous sound data into the synchronous sound data is AMR. The format conversion unit converts the digital sound data format of the vocoder to the sound data format of the EVRC vocoder.

1 is a block diagram of a terminal inside a sound data sharing apparatus of a terminal having a plurality of modems according to an embodiment of the present invention.

2 is a block diagram of a terminal inside a sound data sharing apparatus of a terminal having a plurality of modems according to another embodiment of the present invention.

3 is a flowchart showing an overall operation flow according to a sound data sharing method of a terminal having a plurality of modems according to an embodiment of the present invention.

* Explanation of symbols in the main part of the drawing *

101, 180: terminal 111-1 ~ 111-3: base station

211, 221: Speaker output 212, 222: Microphone input

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

According to an embodiment of the present invention, an apparatus for sharing sound data of a terminal having a plurality of modems uses an adaptive differential pulse code modulation (ADPCM) scheme.

In the present invention, the terminal includes all terminals connected by wire or wireless, such as a PDA terminal, various computers, etc., including a mobile communication terminal.

ADPCM adaptively changes the step size of quantization according to the amplitude of the signal in differential pulse code modulation (DPCM). Only the difference between the predicted value and the actual value is encoded and transmitted.

Two voice transmission standards using the adaptive differential pulse code modulation (ADPCM) scheme have been enacted as ITU-T Recommendations.

ITU-T Recommendation G.721: Sampling is a standard that compresses the frequency to 8 kHz and compresses the number of differential quantized bits into 4 bits and transmits it at 32 kbps. The ADPCM Large Scale Integrated Circuit (LSI) of this standard has been developed to provide voice mail as well as transmission lines. It was incorporated into G.726 in 1990 and is now empty.

ITU-T Recommendation G.722: Sampling is a standard that compresses the frequency to 16 kHz, compresses the number of differential quantization bits to 14 bits, and transmits them at 64 kbps, which is highly consistent with the 64 kbps digital line of the ISDN.

Therefore, in the present invention, the sound data can be supported by both the EVRC modem system and the AMR modem system using the ADPCM method.

The sound data processed by the EVRC modem is stored in the ADPCM, and the sound data processed in the AMR modem is also stored in the ADPCM. When transmitting the sound data wirelessly, the ADPCM sound data is converted into an analog signal and input into the currently operating modem. Then send out.

On the contrary, in case of wirelessly input sound data, the analog signal output from the modem currently in operation is stored in the ADPCM.

1 is a block diagram of a terminal inside a sound data sharing apparatus of a terminal having a plurality of modems according to an embodiment of the present invention.

In FIG. 1, an EVRC vocoder 210 that is a synchronous CDMA modem processor, an AMR vocoder 220 that is an asynchronous WCDMA modem processor, and an ADPCM vocoder 230 are provided.

The microphone (MIC) input terminal 222 of the AMR vocoder 220 is connected to the speaker (SP) output terminal 211 of the EVRC vocoder 210, and the EVRC vocoder is connected to the speaker (SP) output terminal 221 of the AMR vocoder 220. A microphone (MIC) input terminal 212 of 210 is connected.

An ADPCM vocoder 230 is connected to the EVRC vocoder 210 and the AMR vocoder 220.

When the EVRC vocoder 210, which is a synchronous CDMA modem processor, operates in the mobile communication terminal, sound data of the EVRC vocoder 210 format is output as an analog speaker signal from the speaker (SP) output terminal 211 of the EVRC vocoder 210.

The analog speaker signal output from the speaker (SP) output terminal 211 of the EVRC vocoder 210 is input through the microphone as an analog signal through the microphone (MIC) input terminal 222 of the AMR vocoder 220.

Accordingly, the analog sound speaker signal of the EVRC vocoder 210 format output from the speaker (SP) output terminal 211 of the EVRC vocoder 210 is connected to the AMR vocoder (MIC) input terminal 222 of the AMR vocoder 220. An analog sound signal in the format 220 is input through a microphone.

Sound data received through the microphone input terminal 222 of the AMR vocoder 220 is processed as sound data in the AMR vocoder 220 format and stored in the AMR region of the ADPCM vocoder 230.

Therefore, the sound data formats of the EVRC vocoder 210 and the AMR vocoder 220 having different formats are converted into compatible formats so that the mobile communication terminal may be operated in an asynchronous WCDMA mode later. Sound data stored in the AMR area can be used.

On the other hand, when the AMR vocoder 220, which is an asynchronous WCDMA modem processor, is operating in the mobile communication terminal, sound data of the AMR vocoder 220 format is output as an analog speaker signal from the speaker (SP) output terminal 221 of the AMR vocoder 220. do.

The analog speaker signal output from the speaker (SP) output terminal 221 of the AMR vocoder 220 is input through the microphone as an analog signal through the microphone (MIC) input terminal 212 of the EVRC vocoder 210.

Accordingly, the analog speaker sound signal of the AMR vocoder 220 format outputted from the speaker (SP) output terminal 221 of the AMR vocoder 220 is transmitted to the EVRC vocoder (MIC) input terminal 212 of the EVRC vocoder 210. 210) An analog sound signal in a format is input through a microphone.

Sound data input through the microphone input terminal 212 of the EVRC vocoder 210 is processed as sound data in the EVRC vocoder 210 format and stored in the EVRC region of the ADPCM vocoder 230.

Therefore, the sound data formats of the EVRC vocoder 210 and the AMR vocoder 220 having different formats are converted into compatible formats so that the mobile communication terminal may operate in the synchronous CDMA mode later. Sound data stored in the EVRC area can be used.

FIG. 2 is a block diagram of a terminal inside a sound data sharing apparatus of a terminal having a plurality of modems according to another embodiment of the present invention.

In FIG. 2, an EVRC vocoder 210, a synchronous CDMA modem processor, an AMR vocoder 220, an asynchronous WCDMA modem processor, an ADPCM vocoder 230, and a format converter 240 are provided.

The EVRC signal input terminal of the format converter 240 is connected to the digital output terminal of the EVRC vocoder 210, and the EVRC signal input terminal of the format converter 240 is connected to the digital output terminal of the AMR vocoder 220. An output terminal of the 240 is connected to the ADPCM vocoder 230.

When the mobile communication terminal is operating the EVRC vocoder 210, which is a synchronous CDMA modem processor, the sound data of the EVRC vocoder 210 format is converted from the digital output terminal of the EVRC vocoder 210 to the EVRC signal input unit of the format conversion unit 240. Is applied.

Sound data of the EVRC format input through the EVRC signal input terminal of the format converter 240 is converted into sound data of the AMR format by the format converter 240 and then the ADPCM vocoder 230 through the output terminal of the format converter 240. Is stored in the AMR region.

Therefore, the sound data formats of the EVRC vocoder 210 and the AMR vocoder 220 having different formats are converted into compatible formats so that the mobile communication terminal may be operated in an asynchronous WCDMA mode later. Sound data stored in the AMR area can be used.

In contrast to the above operation, the sound data stored in the AMR region of the ADPCM vocoder 230 is converted into sound data of the EVRC format by the format converter 240 and input to the EVRC vocoder 210 to be processed as sound data of a synchronous method. .

On the other hand, when the AMR vocoder 220, which is an asynchronous WCDMA modem processor, is operating in the mobile communication terminal, sound data of the AMR vocoder 220 format is converted from the digital output terminal of the AMR vocoder 220 to the AMR format in the AMR format unit 240. It is applied to the signal input terminal.

Sound data of the AMR format input through the AMR signal input terminal of the format converter 240 is converted into sound data of the EVRC format by the format converter 240, and then ADPCM vocoder 230 through the output of the format converter 240. Is stored in the EVRC region.

Therefore, the sound data formats of the EVRC vocoder 210 and the AMR vocoder 220 having different formats are converted into compatible formats so that the mobile communication terminal may operate in the synchronous CDMA mode later. Sound data stored in the EVRC area can be used.

Contrary to the above operation, the sound data stored in the EVRC region of the ADPCM vocoder 230 is converted into sound data in the AMR format by the format converter 240, input to the AMR vocoder 220, and processed as asynchronous sound data. .

3 is a flowchart illustrating an overall operation flow according to a sound data sharing method of a terminal having a plurality of modems according to an embodiment of the present invention.

In operation 3, the terminal starts operation 401, and determines whether the operation mode of the operating terminal is an operation by a synchronous CDMA modem processor or an operation by an asynchronous WCDMA modem processor (402).

As a result of the determination 402, if the current terminal operation mode is an operation mode by a synchronous CDMA modem processor, the synchronous sound data is converted into asynchronous sound data (403), and then stored (405) in the ADPCM vocoder and the operation ends.

There are various methods for converting the synchronous sound data into asynchronous sound data (403), but the present invention will be described as an example of an analog conversion method and a digital conversion method.

First, the analog conversion method is as follows.

When the EVRC vocoder 210, which is a synchronous CDMA modem processor, operates in the mobile communication terminal, sound data of the EVRC vocoder 210 format is output as an analog speaker signal from the speaker (SP) output terminal 211 of the EVRC vocoder 210.

The analog speaker signal output from the speaker (SP) output terminal 211 of the EVRC vocoder 210 is input through the microphone as an analog signal through the microphone (MIC) input terminal 222 of the AMR vocoder 220.

Accordingly, the analog sound speaker signal of the EVRC vocoder 210 format output from the speaker (SP) output terminal 211 of the EVRC vocoder 210 is transferred to the AMR vocoder (MIC) input terminal 222 of the AMR vocoder 220. An analog sound signal in the format 220 is input through a microphone.

Sound data received through the microphone input terminal 222 of the AMR vocoder 220 is processed as sound data in the AMR vocoder 220 format and stored in the AMR region of the ADPCM vocoder 230.

Therefore, the sound data formats of the EVRC vocoder 210 and the AMR vocoder 220 having different formats are converted into compatible formats so that the mobile communication terminal may be operated in an asynchronous WCDMA mode later. Sound data stored in the AMR area can be used.

Secondly, the digital conversion method is as follows.

When the mobile communication terminal is operating the EVRC vocoder 210, which is a synchronous CDMA modem processor, the sound data of the EVRC vocoder 210 format is converted from the digital output terminal of the EVRC vocoder 210 to the EVRC signal input unit of the format conversion unit 240. Is applied.

Sound data of the EVRC format input through the EVRC signal input terminal of the format converter 240 is converted into sound data of the AMR format by the format converter 240 and then the ADPCM vocoder 230 through the output terminal of the format converter 240. Is stored in the AMR region.

Therefore, the sound data formats of the EVRC vocoder 210 and the AMR vocoder 220 having different formats are converted into compatible formats so that the mobile communication terminal may be operated in an asynchronous WCDMA mode later. Sound data stored in the AMR area can be used.

In contrast to the above operation, the sound data stored in the AMR region of the ADPCM vocoder 230 is converted into sound data of the EVRC format by the format converter 240 and input to the EVRC vocoder 210 to be processed as sound data of a synchronous method. .

As a result of the determination 402, if the current terminal operation mode is the operation mode of the asynchronous WCDMA modem processor, the asynchronous sound data is converted into synchronous sound data (404), and then stored (405) in the ADPCM vocoder and the operation ends.

There are various methods for converting the asynchronous sound data into synchronous sound data (404), but the present invention will be described as an example of an analog conversion method and a digital conversion method.

First, the analog conversion method is as follows.

When the AMR vocoder 220, which is an asynchronous WCDMA modem processor, operates in the mobile communication terminal, sound data of the AMR vocoder 220 format is output as an analog speaker signal from the speaker (SP) output terminal 221 of the AMR vocoder 220.

The analog speaker signal output from the speaker (SP) output terminal 221 of the AMR vocoder 220 is input through the microphone as an analog signal through the microphone (MIC) input terminal 212 of the EVRC vocoder 210.

Accordingly, the analog speaker sound signal of the AMR vocoder 220 format outputted from the speaker (SP) output terminal 221 of the AMR vocoder 220 is transmitted to the EVRC vocoder (MIC) input terminal 212 of the EVRC vocoder 210. 210) An analog sound signal in a format is input through a microphone.

Sound data input through the microphone input terminal 212 of the EVRC vocoder 210 is processed as sound data in the EVRC vocoder 210 format and stored in the EVRC region of the ADPCM vocoder 230.

Therefore, the sound data formats of the EVRC vocoder 210 and the AMR vocoder 220 having different formats are converted into compatible formats so that the mobile communication terminal may operate in the synchronous CDMA mode later. Sound data stored in the EVRC area can be used.

Secondly, the digital conversion method is as follows.

When the AMR vocoder 220, which is an asynchronous WCDMA modem processor, is operating in the mobile communication terminal, sound data of the AMR vocoder 220 format is converted from the digital output of the AMR vocoder 220 to the AMR format input unit of the AMR signal input unit 240. Is applied.

Sound data of the AMR format input through the AMR signal input terminal of the format converter 240 is converted into sound data of the EVRC format by the format converter 240, and then ADPCM vocoder 230 through the output of the format converter 240. Is stored in the EVRC region.

Therefore, the sound data formats of the EVRC vocoder 210 and the AMR vocoder 220 having different formats are converted into compatible formats so that the mobile communication terminal may operate in the synchronous CDMA mode later. Sound data stored in the EVRC area can be used.

Contrary to the above operation, the sound data stored in the EVRC region of the ADPCM vocoder 230 is converted into sound data in the AMR format by the format converter 240, input to the AMR vocoder 220, and processed as asynchronous sound data. .

As described in detail above, the present invention processes the sound data being used by the modem chips having different formats in each terminal chip which is equipped with the synchronous CDMA modem chip and the asynchronous WCDMA modem chip so that they can be shared by each modem chip. In addition, the DBDM system that uses synchronous and asynchronous modem chips with different formats can share sound data and thus make efficient use of system resources.

Claims (5)

In the sound data sharing apparatus of a terminal having a plurality of modem processors, An AMR vocoder for receiving an analog speaker signal output from the speaker output terminal of the synchronous EVRC vocoder of the terminal as an analog signal through a microphone input terminal; An EVRC vocoder that receives an analog speaker signal output from the speaker output terminal of the asynchronous AMR vocoder of the terminal as an analog signal through a microphone input terminal; And an ADPCM vocoder for processing and storing sound data of the AMR vocoder and the EVRC vocoder. In the sound data sharing apparatus of a terminal having a plurality of modem processors, An EVRC vocoder operable to process sound data in EVRC format in a synchronous CDMA mode of the terminal; An AMR vocoder operable to process sound data in AMR format in asynchronous WCDMA mode of the terminal; A format converter for converting different sound data formats of the EVRC vocoder and the AMR vocoder into the same sound data format; Sound data sharing of the terminal having a plurality of modems comprising an ADPCM vocoder for storing the sound data of the EVRC format received through the output of the format conversion unit in the EVRC region and the AMR format sound data in the AMR region Device. The method according to claim 2, The synchronous sound data stored in the EVRC region of the ADPCM vocoder is converted into sound data in AMR format by a format converter, and then input to an AMR vocoder and processed as asynchronous sound data. Sound data sharing device. The method according to claim 2, The asynchronous sound data stored in the AMR region of the ADPCM vocoder is converted into sound data of an EVRC format by a format converter, and then input to an EVRC vocoder and processed as synchronous sound data. Sound data sharing device. In the sound data sharing method of a terminal having a plurality of modem processors, Determining whether the operation mode is an operation by a synchronous CDMA modem processor or an operation by an asynchronous WCDMA modem processor when the terminal starts operation; If the current terminal operation mode is an operation mode by a synchronous CDMA modem processor, converting the synchronous sound data into asynchronous sound data and storing the same in the ADPCM vocoder; And if the current terminal operation mode is an asynchronous WCDMA modem processor, converting the asynchronous sound data into the synchronous sound data and storing the same in the ADPCM vocoder. Sound data sharing method.