KR100452137B1 - A dual channel phone - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a dual channel mobile phone, and more particularly, to a mobile phone embodying a transmission and reception channel of a radio frequency unit in a dual manner of a call channel and a data channel, respectively. The present invention provides a mobile phone having a reception channel section and a transmission channel section having dual channels of a voice communication channel and a data communication channel, respectively, wherein the reception channel section is a source of a low noise amplified data signal received by an antenna and filtered. A first mixer section for extracting a signal, a first amplifier section for amplifying the original signal of the data signal extracted from the first mixer section, and a demodulator for demodulating the original signal of the data signal amplified from the first amplifier section; A data signal receiving channel section comprising a first demodulation section; A second mixer for extracting an original signal of the low noise amplified voice signal received by the antenna and filtered, a second amplifier for amplifying the original signal of the voice signal extracted from the second mixer, and the second signal; A second signal demodulating section comprising a second demodulating section for demodulating the original signal of the voice signal amplified by the amplifying section, and the first channel for receiving and modulating the demodulated voice signal inputted through a microphone A first phase modulator for modulating a phase of the voice signal modulated from the first modulator, a first phase detector for detecting and processing a phase of the voice signal modulated from the first phase modulator; A first voltage controlled oscillator for generating an antenna transmission signal of the voice signal phase processed from the first phase detector and a first voltage controlled oscillator generated from the first voltage controlled oscillator A voice signal transmission channel section comprising a first power amplifier for amplifying the antenna transmission signal of the voice signal; A second modulator for receiving and modulating a data signal under the control of a microprocessor, a second phase modulator for modulating a phase of the data signal modulated from the second modulator, and a modulation from the second phase modulator; A second phase detector configured to detect and process a phase of the data signal, a second voltage controlled oscillator for generating an antenna transmission signal of the data signal phased from the second phase detector, and the second voltage controlled oscillator And a data signal transmission channel section comprising a second power amplifier for amplifying the antenna transmission signal of the generated data signal.

Description

Dual channel mobile phone {A DUAL CHANNEL PHONE}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a dual channel mobile phone, and more particularly, to a mobile phone embodying a transmission and reception channel of a radio frequency unit in a dual manner of a call channel and a data channel, respectively.

Typically, Global System for Mobile Communication (GSM) is a variant of Time Division Multiple Access (TDMA), a digital mobile telephone system widely used in Europe and elsewhere. In Europe, in particular, it is the de facto standard for cordless telephones, with over 120 million users worldwide and used in 120 countries. The GSM scheme, which is a European standard, proposes an 8-time slot TDMA scheme in which the transmission rate is 270.833 Kbps and the RF transmission channel bandwidth of 200 KHz. The channel usage method in GSM uses a logical channel mapped to a physical channel such as an RF channel, a TDMA frame, and a timeslot, and the types of logical channels include a traffic channel (TCH) and a control channel (BCCH). , PCH, RACH, AGCH, SDCCH, SACCH, FACCH). The traffic channel transmits information such as voice (13 Kbps) and data (9.6 Kbps, 4.8 Kbps, 2.4 Kbps), and among the control channels, BCCH, PCH, RACH, AGCH, etc. are common control channels. Transmit / receive paging and access parameter (PCH) and access attempt (RACH) signals for the control signal with the SDCCH, SACCH, FACCH, etc. Authentication and location registration, SACCH is a system information, Mobile Assisted Hand Over (MAHO), FACCH is a logical channel used for handover. The TDMA frame and timeslot structure consists of one TDMA frame (4.615ms) with eight timeslots and one timeslot with 156.25 bits (0.5769ms).

In addition, the GPRS (General Packet Radio Service), which is a packet-based wireless communication service based on the GSM method, is intended to increase the communication speed of data transmitted through the traffic channel in the GSM method. 2.5G mobile phone technology.

However, in the GSM or GPRS mobile phone, a voice call or data communication is performed using a single traffic channel. Accordingly, there is a problem that voice calls and data communication cannot be performed at the same time.

Accordingly, an object of the present invention is to provide a dual channel mobile phone configured to simultaneously perform a voice call and data communication by configuring a radio frequency unit in a dual channel in a GSM or GPRS mobile phone.

A dual channel mobile phone according to an embodiment of the present invention for achieving the above object is a mobile phone configured with a dual channel of a voice communication channel and a data communication channel, respectively, the receiving channel unit and the transmitting channel unit of the radio frequency unit, the receiving channel unit is an antenna A first mixer for extracting the original signal of the received and filtered low noise amplified data signal, a first amplifier for amplifying the original signal of the data signal extracted from the first mixer, and the first amplifier A data signal receiving channel section comprising a first demodulation section for demodulating the original signal of the data signal amplified by the first signal; A second mixer for extracting an original signal of the low noise amplified voice signal received by the antenna and filtered, a second amplifier for amplifying the original signal of the voice signal extracted from the second mixer, and the second signal; A second signal demodulating section comprising a second demodulating section for demodulating the original signal of the voice signal amplified by the amplifying section, and the first channel for receiving and modulating the demodulated voice signal inputted through a microphone A first phase modulator for modulating a phase of the voice signal modulated from the first modulator, a first phase detector for detecting and processing a phase of the voice signal modulated from the first phase modulator; A first voltage controlled oscillator for generating an antenna transmission signal of the voice signal phase processed from the first phase detector and a first voltage controlled oscillator generated from the first voltage controlled oscillator A voice signal transmission channel section comprising a first power amplifier for amplifying the antenna transmission signal of the voice signal; A second modulator for receiving and modulating a data signal under the control of a microprocessor, a second phase modulator for modulating a phase of the data signal modulated from the second modulator, and a modulation from the second phase modulator; A second phase detector configured to detect and process a phase of the data signal, a second voltage controlled oscillator for generating an antenna transmission signal of the data signal phased from the second phase detector, and the second voltage controlled oscillator And a data signal transmission channel section comprising a second power amplifier for amplifying the antenna transmission signal of the generated data signal.

1 is a block diagram showing a radio frequency unit of a GSM phone according to an embodiment of the present invention.

2 is a diagram illustrating a state where a voice call and data communication are simultaneously performed using a dual channel of a GSM phone according to an embodiment of the present invention.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, detailed descriptions of preferred embodiments of the present invention will be described with reference to the accompanying drawings. It should be noted that the same components in the figures represent the same numerals wherever possible.

1 is a block diagram showing a radio frequency unit of a GSM phone according to an embodiment of the present invention.

As shown, the configuration of the present invention is largely divided into an antenna 10, an antenna switch unit 20, an RF filter 30, a low noise amplifier (LNA) 40 and the like. Mixers 50a and 50b, programmable gain amplifier (PGA) amplifiers 60a and 60b, digital signal processing (DSP) 70, audio unit 80, and I / Q modulators 90a and 90b, phase detectors 100a and 100b, voltage control oscillators (VCOs) 110a and 110b, and power amplifiers 120a and 120b) and a low pass filter (LPF) 130.

The digital signal processor 70 is composed of a release buffer 71a, 71b, demodulators 72a, 72b, modulators 73a, 73b, and encryption buffers 74a, 74b.

The radio frequency filter 30 receives the signal received by the antenna 10 through the antenna switch 20 to filter the frequency for each band.

The low noise amplifier 40 receives the filtered signal through the RF filter 30 and amplifies the signal to low noise.

And, the mixer (50a, 50b) is composed of a double. That is, the mixers 50a and 50b receive a data signal received by the antenna 10 through the radio frequency filter 30 and the low noise amplifier 40 and mix a reference frequency for the data signal. A first mixer 50a extracting a signal and a voice signal received by the antenna 10 are input through the RF filter 30 and the low noise amplifier 40 to mix a reference frequency for the voice signal. And a second mixer 50b for extracting the original signal.

The PGA amplifiers 60a and 60b are also doubled as in the mixers 50a and 50b. That is, the PGA amplifiers 60a and 60b may include a first PGA amplifier 60a and a second mixer 50b for amplifying an original signal for the data signal extracted through the first mixer 50a. It consists of a second PGA amplifier 60b for amplifying the original signal for the speech signal extracted through.

In addition, the digital signal processing unit 70 is also dually configured like the mixers 50a and 50b and the PGA amplifiers 60a and 60b. That is, a first release buffer 71a for releasing encryption of the original signal for the data signal amplified by the first PGA amplifier 60a, and the voice amplified by the second PGA amplifier 60b. And a second decryption buffer 71b for decrypting the original signal for the signal.

In addition, the digital signal processing unit 70 may demodulate the signal released from the first release buffer 71a and the signal released from the second release buffer 71b. And a second demodulation section 72b for demodulation.

The audio unit 80 receives the demodulated signal from the second demodulator 72b and restores the audio signal.

In addition, the digital signal processing unit 70 modulates a voice signal input from the audio unit 80 and converted into a digital signal by an analog-to-digital conversion (ADC) (not shown). And a first encryption buffer 74a for receiving and encrypting the voice signal modulated by the first modulator 73a.

In addition, the digital signal processor 70 is connected to a processor (not shown) to receive and modulate a data signal input under the control of the processor, and a second modulator 73b and the second modulator 73b. A second encryption buffer 74b for receiving and encrypting the data signal modulated by the < RTI ID = 0.0 >

The I / Q modulators 90a and 90b are also dual. That is, the first I / Q modulator 90a modulating the phase of the voice signal encrypted by the first encryption buffer 74a and the phase of the data signal encrypted by the second encryption buffer 74b. And a second I / Q modulator 90b for modulating.

The phase detectors 100a and 100b are also doubled as in the I / Q modulators 90a and 90b. That is, the first phase detector 100a detects and processes the phase of the voice signal phase-modulated from the first I / Q modulator 90a and the phase modulated from the second I / Q modulator 90b. The second phase detector 100b detects and processes a phase of the data signal.

In addition, the voltage controlled oscillators 110a and 110b are also dually configured like the I / Q modulators 90a and 90b and the phase detectors 100a and 100b. That is, a first voltage controlled oscillator 110a for mixing a reference frequency with respect to the voice signal processed by the first phase detector 100a to actually output a signal to be transmitted through the antenna 10, and the second And a second voltage controlled oscillator 110b that mixes the reference frequencies for the phase-processed data signals from the phase detector 100b to actually generate a signal to be transmitted through the antenna 10.

In addition, the power amplifiers 120a and 120b are also dually configured like the I / Q modulators 90a and 90b, the phase detectors 100a and 100b, and the voltage controlled oscillators 110a and 110b. That is, the first power amplifier 120a amplifies the signal generated from the first voltage controlled oscillator 110a and the second power amplifier 120b amplifies the signal generated from the second voltage controlled oscillator 110b. It consists of.

The low pass filter 130 receives signals amplified from the first power amplifier 120a and the second power amplifier 120b and removes harmonics to pass only a frequency lower than the cutoff frequency.

2 is a diagram illustrating a state where a voice call and data communication are simultaneously performed using a dual channel of a GSM phone according to an embodiment of the present invention.

As shown, a communication channel consisting of 80 channels and a data channel consisting of 60 channels are divided into 8 time slots according to the GSM method. Here, when a voice signal is received through the communication channel in time slot 0 of the 8 time slots and a data signal is received through the data channel, as described with reference to FIG. 1, the data signal is a first mixer of the data channel. The original signal is extracted by mixing with the reference frequency for the data signal by 50a, and at the same time the voice signal is mixed with the reference frequency for the voice signal by the second mixer 50b of the call channel. The signal is extracted.

Subsequently, the original signal of the data signal extracted by the first mixer 50a of the data channel is amplified by the first PGA amplifier 60a and at the same time by the second mixer 50b of the call channel. The original signal of the extracted voice signal is amplified by the second PGA amplifier 60b.

Subsequently, the original signal of the data signal amplified by the first PGA amplifier 60a is decoded by the first release buffer 71a of the digital signal processor 70 and then the first demodulator 72a. The original signal of the voice signal amplified by the second PGA amplifier 60b is decoded by the second release buffer 71b and then decoded by the second demodulator 72b. Demodulated by Here, the signal demodulated by the second demodulation unit 72b is transmitted to the audio unit 80 to restore the audio signal.

Meanwhile, when a voice signal is input through a call channel in 4 time slots among the 8 time slots and a data signal is input through a data channel, as described with reference to FIG. 1, the voice signal is converted into a digital signal by an analog / digital converter. As a result, the signal is modulated by the first modulator 73a of the digital signal processor 70 and then encrypted by the first encryption buffer 74a. At the same time, the data signal is modulated by the second modulator 73b. And then encrypted by the second encryption buffer 74b.

Subsequently, the voice signal encrypted by the first encryption buffer 74a of the digital signal processor 70 is phase-modulated by the first I / Q modulator 90a of the communication channel, and at the same time, the second The data signal encrypted by the encryption buffer 74b is phase modulated by the second I / Q modulator 90b of the data channel.

Subsequently, the voice signal whose phase is modulated by the first I / Q modulator 90a of the communication channel is detected and processed by the first phase detector 100a, and at the same time, the second I of the data channel is processed. The phase signal modulated by the / Q modulator 90b is processed by the phase detected by the second phase detector 100b.

Subsequently, the voice signal phase-processed by the first phase detector 100a is mixed with a reference frequency by the first voltage controlled oscillator 110a to be generated as a signal to be actually transmitted through the antenna 10, and at the same time the The data signal phase-processed by the second phase detector 100b is mixed with the reference frequency by the second voltage controlled oscillator 110b to be actually generated as a signal to be transmitted through the antenna 10.

Subsequently, the outgoing signal generated by the first voltage controlled oscillator 110a is amplified by the first power amplifier 120a, and at the same time, the outgoing signal generated by the second voltage controlled oscillator 110b is obtained by the second signal. Amplified by power amplifier 120b.

Subsequently, the transmission signals amplified by the first power amplifier 120a and the second power amplifier 120b are removed through harmonics through the low pass filter 130 so that only frequencies lower than the cutoff frequency pass.

Subsequently, the transmission signal passing through the low pass filter 130 is transmitted to the antenna 10 through the antenna switch unit 20.

The call channel and the data channel are simultaneously monitored in 6 time slots of the 8 time slots.

In the above description of the present invention, specific embodiments have been described, but various modifications can be made without departing from the scope of the present invention. Therefore, the scope of the present invention should not be defined by the described embodiments, but should be defined by the equivalent of claims and claims.

As described above, the radio frequency unit of the mobile phone is configured in dual channels, so that voice calls and data communication can be simultaneously performed.

Claims (3)

In a mobile phone comprising a reception channel section and a transmission channel section of a radio frequency section composed of dual channels of a voice call channel and a data communication channel, respectively, The reception channel unit is a first mixer for extracting the original signal of the low noise amplified data signal received by the antenna and filtered, a first amplifier for amplifying the original signal of the data signal extracted from the first mixer; A data signal receiving channel section comprising a first demodulation section for demodulating the original signal of the data signal amplified by the first amplifier section; A second mixer for extracting an original signal of the low noise amplified voice signal received by the antenna and filtered, a second amplifier for amplifying the original signal of the voice signal extracted from the second mixer, and the second signal; A voice signal receiving channel section comprising a second demodulation section for demodulating the original signal of the voice signal amplified by the second amplifying section, The first channel modulator for receiving and modulating a demodulated voice signal input through a microphone, a first phase modulator for modulating a phase of the voice signal modulated from the first modulator, and the first modulator; A first phase detector for detecting and processing a phase of the voice signal modulated by the phase modulator, a first voltage controlled oscillator for generating an antenna transmission signal of the voice signal phase processed from the first phase detector, and the first phase detector; A voice signal transmission channel section comprising a first power amplifier for amplifying an antenna transmission signal of the voice signal generated from one voltage controlled oscillator; A second modulator for receiving and modulating a data signal under the control of a microprocessor, a second phase modulator for modulating a phase of the data signal modulated from the second modulator, and a modulation from the second phase modulator; A second phase detector configured to detect and process a phase of the data signal, a second voltage controlled oscillator for generating an antenna transmission signal of the data signal phased from the second phase detector, and the second voltage controlled oscillator And a data signal transmission channel section comprising a second power amplifier for amplifying the antenna transmission signal of the generated data signal. The method of claim 1, And an audio unit configured to receive an original signal of the voice signal demodulated by the second demodulation unit and restore the audio signal to an audio signal. The method of claim 1, The antenna transmission signal of the voice signal amplified by the first power amplifier of the voice signal transmission channel section and the antenna transmission signal of the data signal amplified by the second power amplifier of the data signal transmission channel section are respectively passed in a low range And a low pass filter to the antenna.