JP2006238340A - Communication terminal device and communication method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a communication terminal device applicable to multiple communication methods and compatible with a dual mode, and enabling handover between the multiple communication methods. <P>SOLUTION: The communication terminal device is applicable to the multiple wireless communication methods and includes reception means applicable to the multiple wireless communication methods (1, 2, 3, 4-1, 4-2, 5-1, 5-2, 6-1, 6-2, 7-1, 7-2, 8-1, 8-2, 19-1, 19-2), transmission means (9-1, 9-2, 10-1, 10-2, 11, 12, 13, 14, 2, 1), and communication means for controlling the reception means and the transmission means and for performing handover between the multiple wireless communication methods (18, 15, 16, 17). <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a communication terminal device such as a mobile phone and a PDA, and in particular, a dual mode compatible type capable of sharing two communication methods of a GSM (Global Systems for Mobile Communications) method and a WCDMA (Wide Band CDMA) method. The present invention relates to a communication terminal device and a communication method.

  Mobile phone operators tend to use multiple communication systems in the exact same frequency band using existing base stations that have been used in the past, from the viewpoint of restraining new capital investment and effectively utilizing assets held. There is a high possibility that it will become full-scale in the future. For example, in Japan, the PDC system and the W-CDMA system can coexist, and in the United States, the US PCS system and the W-CDMA system can coexist.

  If the movement to use a plurality of communication methods becomes full-scale, a dual-mode compatible communication terminal device in the same frequency band will be essential.

  For this reason, as a technical document filed earlier than the present invention, a transmitter / receiver shared by the GSM scheme and the WCDMA scheme, and a transmission circuit in the transceiver, the GSM transmission signal or the A modulation unit that generates a WCDMA transmission signal; a mixer that is provided in a receiving circuit of the transceiver; and that receives the GSM reception signal or the WCDMA reception signal; a first oscillator; and a second oscillator When the transmitter / receiver is used for the GSM system, the oscillation signal output from the first oscillator is supplied to the modulator and the mixer, and the transmitter / receiver is used for the WCDMA system. When the oscillation signal output from the first oscillator is supplied to the modulator, and the oscillation signal output from the second oscillator is mixed with the oscillation signal. The supply, by changing the frequency band of the oscillator operating in correspondence with each method, there is a particular mobile phone to reduce the current consumption of the oscillator in the WCDMA system (e.g., see Patent Document 1).

In addition, a multimode communication apparatus compatible with different wireless communication systems, a modulation unit and a demodulation unit capable of supporting a plurality of wireless communication systems, and a variable bandwidth type high-frequency front end shared in the plurality of wireless communication systems And a control unit that switches the frequency characteristics of the band-variable high-frequency front end according to the radio communication system that is actually used, and is demanded of portable communication terminals that are small, light, and have low power consumption. There is a multi-mode communication apparatus that can respond to a request and that is compatible with different wireless communication modes (see, for example, Patent Document 2).
JP 2004-88401 A JP 2004-320446 A

  Although the above Patent Documents 1 and 2 are dual-mode compatible communication terminal devices applicable to a plurality of communication methods, the above Patent Document 1 switches between a first oscillator and a second oscillator. Since either GSM or WCDMA communication method is applied, communication is established only with one communication method, and handover between multiple communication methods can be established. There is nothing to consider about doing. In addition, Patent Document 2 does not take into consideration that handover is performed between a plurality of communication methods as in Patent Document 1.

  The present invention has been made in view of the above circumstances, and provides a communication terminal apparatus and a communication method capable of performing handover between a plurality of communication systems in a dual-mode compatible communication terminal apparatus applicable to a plurality of communication systems. It is intended to provide.

  In order to achieve this object, the present invention has the following features.

  A communication terminal apparatus according to the present invention is a communication terminal apparatus applicable to a plurality of wireless communication systems, and controls a receiving means and a transmitting means applicable to a plurality of wireless communication systems, a receiving means and a transmitting means, And a communication means for performing handover between a plurality of wireless communication systems.

  In the communication terminal apparatus according to the present invention, the receiving means is a direct conversion system.

  In the communication terminal device according to the present invention, the receiving means includes an antenna that receives the received signal, a separating means that separates the received signal received by the antenna into signals corresponding to a plurality of wireless communication systems, and a separating means. And a control unit that controls the separated signal using a wireless communication method corresponding to the signal.

  Further, in the communication terminal device according to the present invention, the transmission means includes a transmission signal generation means for generating a transmission signal corresponding to a plurality of wireless communication schemes, and an antenna for transmitting the transmission signal generated by the transmission signal generation means. It is characterized by having.

  Further, the communication terminal apparatus according to the present invention is characterized in that the antenna of the receiving means and the antenna of the transmitting means comprise a common antenna.

  Further, the communication terminal apparatus according to the present invention is characterized in that the antenna of the receiving means and the antenna of the transmitting means are composed of different antennas.

  Further, in the communication terminal apparatus according to the present invention, the control means mixes with a local signal having the same frequency as the signal separated by the separation means, and obtains a baseband signal from the signal, and the separation means Signal strength detection means for detecting the signal strength of the signal separated by the control means, and the control means uses the baseband signal acquired by the signal component acquisition means and the signal strength detected by the signal strength detection means Then, the signal separated by the separating means is controlled using a radio signal system corresponding to the signal.

  The communication terminal apparatus according to the present invention is characterized by having a local signal generating means for generating a local signal.

  In the communication terminal apparatus according to the present invention, the transmission signal generating means generates the transmission signal using the local signal generated by the local signal generating means.

  In the communication terminal apparatus according to the present invention, the communication means controls the reception means and the transmission means at the time of shifting to the compressed mode, and performs handover between a plurality of wireless communication systems.

  The communication method according to the present invention is a communication method performed in a communication terminal apparatus applicable to a plurality of wireless communication systems, and includes a reception step of receiving a reception signal and a reception signal received by the reception step. The communication terminal apparatus performs a control process for controlling using a radio communication scheme corresponding to a signal and a handover process for switching from a radio communication scheme corresponding to a received signal to a different radio communication scheme. .

  In the communication method according to the present invention, the receiving step is performed by a direct conversion method.

  In the communication method according to the present invention, the communication terminal device performs a separation step of separating the received signal received in the reception step into signals corresponding to a plurality of wireless communication schemes, and the control step is separated by the separation step. The signal is controlled using a wireless communication method corresponding to the signal.

  Further, the communication method according to the present invention includes a transmission signal generation step for generating a transmission signal corresponding to a plurality of wireless communication schemes, and a transmission step for transmitting the transmission signal generated by the transmission signal generation step. It is characterized by doing.

  In the communication method according to the present invention, the reception step and the transmission step are performed using a common antenna.

  In the communication method according to the present invention, the reception step and the transmission step are performed by different antennas.

  In addition, the communication method according to the present invention includes a signal component acquisition step of mixing a local oscillation signal having the same frequency as the signal separated by the separation step, and obtaining a baseband signal from the signal separated by the separation step. The signal strength detection step of detecting the signal strength of the signal separated by the step is performed by the communication terminal device, and the control step is the baseband signal acquired by the signal component acquisition step and the signal detected by the signal strength detection step The signal separated by the separation step is controlled by using a radio signal system corresponding to the signal.

  The communication method according to the present invention is characterized in that the communication terminal apparatus performs a local signal generation step for generating a local signal.

  In the communication method according to the present invention, the transmission signal generation step generates the transmission signal using the local signal generated in the local signal generation step.

  In the communication method according to the present invention, the handover step is performed when the compression mode is shifted.

  According to the present invention, a communication terminal apparatus that can be applied to a plurality of wireless communication schemes, and that can control a plurality of wireless communication schemes by controlling reception means and transmission means that can be applied to a plurality of wireless communication schemes. Communication means for performing a handover between communication methods, a dual-mode compatible communication terminal apparatus applicable to a plurality of communication methods enables handover between the plurality of communication methods.

  First, the communication terminal device according to the present embodiment will be described with reference to FIG.

  The communication terminal apparatus according to the present embodiment is a communication terminal apparatus applicable to a plurality of wireless communication systems, and is a receiving unit (1, 2, 3, 4-1, 4-2 applicable to a plurality of wireless communication systems. 5-1, 5-2, 6-1, 6-2, 7-1, 7-2, 8-1, 8-2, 19-1, 19-2) and transmission means (9-1, 9). -2, 10-1, 10-2, 11, 12, 13, 14, 2, 1) and communication means (18, 15) for controlling the reception means and transmission means and performing handover between a plurality of wireless communication systems. , 16, 17). With the above configuration, a dual-mode compatible communication terminal apparatus applicable to a plurality of communication schemes can perform handover between the plurality of communication schemes. Hereinafter, the communication terminal device according to the present embodiment will be described with reference to the accompanying drawings.

  First, the communication terminal device according to the present embodiment will be described with reference to FIG. FIG. 1 shows the internal configuration of a dual-mode compatible communication terminal device in this embodiment.

  The communication terminal apparatus according to the present embodiment includes a reception unit side and a transmission unit side. The reception unit side includes a transmission / reception antenna (1), a DUP (Duplexer) (2), and an LNA (Low). Noise Amplifier (3), MIXER circuit (4-1, 4-2), local oscillator (5-1, 5-2), PGA (Programmable Gain Amplifier) (6-1, 6-2) LPF (7-1, 7-2), RX B. B. (Base Band) section (8-1, 8-2), compressed mode transition signal generation section (18), and RSSI section (19-1, 19-2).

  In addition, the TX side can transmit TX B. B. (Base Band) section (9-1, 9-2), TX IQ section (10-1, 10-2), path switch (11), quadrature modulation section (12), DRV (Driver Amplifier) ) (13), PA (Power Amplifier) (14), IF Local unit (15), carrier wave generation unit (16), carrier wave buffer unit (17), DUP (Duplexer) (2), and transmission / reception Antenna (1).

  As shown in FIG. 1, the communication terminal apparatus according to the present embodiment includes a transmitting / receiving antenna (1), a DUP (Duplexer) (2), and an LNA (Low Noise Amplifier) (3) on the receiving side. PGA (Programmable Gain Amplifier) (GGA) and W-CDMA signals corresponding to each communication method are collected in one system and distributed from the MIXER circuit (4-1, 4-2) to two systems. 6-2, 6-2) and LPF (7-1, 7-2), RX B. is a control unit corresponding to each communication method. B. It is the structure which outputs to a part (8-1, 8-2).

  Also, RSSI units (19-1, 19-2) corresponding to the respective communication methods are provided, and in the provided RSSI units (19-1, 19-2), PGA (Programmable Gain Amplifier) (6-1, 6-2) detects the signal strength of the signal received from the MIXER circuit (4-1, 4-2), and uses the detected signal strength for each RX B.B. B. It is the structure which outputs to a part (8-1, 8-2).

  On the other hand, on the transmission side, TX B.B, which is a control unit corresponding to each communication method. B. The IQ signals output from the base (Base Band) (9-1, 9-2) are received by the TX IQ units (10-1, 10-2) corresponding to each communication method, and the received IQ signals are received. Via a path changeover switch (11), a quadrature modulation unit (12) combined into one system, a DRV (Driver Amplifier) (13), a PA (Power Amplifier (14)), a DUP (Duplexer) (2), , Through the transmitting / receiving antenna (1).

  In addition, a compressed mode transition signal generation unit (18) for generating a compressed mode transition signal at the time of transition to the compressed mode is provided. When the mode is shifted to the compressed mode, the compressed mode transition signal generation unit (18) A mode transition signal is generated, and both types of MIXER circuits (4-1, 4-2) and GSM RX B.B. B. Unit (8-2) is controlled to enable handover between a plurality of communication methods.

  As described above, the communication terminal apparatus according to the present embodiment is a dual-mode (GSM system and W-CDMA system) compatible communication terminal apparatus that can be applied to a plurality of communication systems in the same frequency band. In order to cope with two different communication systems using a conversion system, one system is received from the transmitting / receiving antenna (1) to the LNA (3), and two systems are received after the MIXER circuit (4-1, 4-2). With the circuit configuration, a part of the reception circuit and the transmission circuit can be shared, the integration degree of the radio circuit can be improved, and the communication terminal device can be downsized.

  In addition, when the mode is shifted to the compressed mode, a compressed mode shift signal is generated to control the gain switching of the MIXER circuit (4-1, 4-2) or to measure the WSM at the time of measuring the GSM reception level. -Handover between a plurality of communication systems is enabled by controlling so as to reduce the influence of the CDMA system.

  Next, the communication terminal device of the present embodiment shown in FIG. 1 will be described in comparison with the conventional communication terminal device shown in FIG.

  First, a conventional communication terminal device will be described with reference to FIG. FIG. 2 is a diagram illustrating an internal configuration of a conventional communication terminal device.

  As shown in FIG. 2, the conventional communication terminal apparatus is provided with W-CDMA and GSM radio circuits independently.

  First, a W-CDMA wireless circuit of a conventional communication terminal apparatus will be described.

(W-CDMA system)
The W-CDMA radio circuit is composed of a reception unit side and a transmission unit side. The reception unit side includes a W-CDMA transmission / reception antenna (101-1) and a DUP (Duplexer) (102). W-LNA (103-1), W-MIXER circuit (104-1), W-local oscillator (105-1), W-PGA (106-1), and W-LPF (107 -1) and WCDMA RX B.1. B. Part (108-1) and a W-RSSI part (119-1).

  In addition, the transmission side is WCDMA TX B.B. B. Section (109-1), WCDMA TX IQ section (110-1), W-orthogonal modulation section (111-1), W-local oscillator section (112-1), and W-DRV (113-1) ), W-PA (114-1), DUP (Duplexer) (102), and W-CDMA transmission / reception antenna (101-1).

(W-CDMA receiver side)
First, the W-CDMA receiver unit will be described.
On the W-CDMA receiver side, a signal is received by the W-CDMA transmission / reception antenna (101-1), and the received signal is input to the DUP (102). The DUP (102) inputs the signal input from the W-CDMA transmission / reception antenna (101-1) to the W-LNA (103-1) side, and the W-LNA (103-1) The signal input from is amplified.

  The W-LNA (103-1) inputs the amplified signal to the W-MIXER circuit (104-1), and the W-MIXER circuit (104-1) inputs to the W-MIXER circuit (104-1). The signal is mixed with the W-local signal (Local signal) (105-1) having the same frequency as the received signal, and only the baseband signal is obtained from the signal input from the W-LNA (103-1). .

  The W-MIXER circuit (104-1) inputs the acquired baseband signal to the W-PGA (106-1), and the W-PGA (106-1) receives the W-MIXER circuit (104-1). Is input to the W-LPF (107-1), and the W-LPF (107-1) transmits the input signal to the WCDMA RX B. B. Part (108-1).

  The W-PGA (106-1) inputs the signal input from the W-MIXER circuit (104-1) to the W-RSSI unit (119-1), and the W-RSSI unit (119-1) , W-PGA (106-1) is used to detect the signal strength of the signal, and the detected signal strength is detected using WCDMA RX B.B. B. Part (108-1).

(W-CDMA transmitter side)
Next, the transmitting unit side of W-CDMA will be described.
On the transmitter side of W-CDMA, WCDMA TX B.B. B. The IQ signal output from the unit (109-1) is received by the WCDMA TX IQ unit (110-1), and the received IQ signal is received by the W-orthogonal modulation unit (111-1) as a W-local signal (Local signal). ) (112-1) to generate a transmission wave. The W-orthogonal modulation unit (111-1) inputs the generated transmission wave to the W-DRV (113-1).

  Since the W-DRV (113-1) is a variable gain amplifier, the input transmission wave is amplified to a required output level, and the amplified transmission wave is input to the W-PA (114-1).

  The W-PA (114-1) amplifies the transmission wave input from the W-DRV (113-1) to a level that can be output from the W-CDMA transmission / reception antenna (101-1), and the amplified transmission The signal is output to the DUP (102), and the transmission signal is transmitted from the W-CDMA transmission / reception antenna (101-1).

  Note that since the W-CDMA system is a signal system in which the reception unit side and the transmission unit side operate simultaneously, the DUP (102) performs a separation process between the reception signal and the transmission signal, and the DUP (102 ) Controls the signal level so that the transmission signal input from the transmission unit side does not enter the reception unit side.

(GSM method)
Next, a GSM wireless circuit will be described.
Similar to the W-CDMA wireless circuit, the GSM wireless circuit is composed of a receiving unit side and a transmitting unit side. The receiving unit side includes a GSM transmitting / receiving antenna (101-2), ANT SW (antenna switch) (115), G-LNA (103-2), G-MIXER circuit (104-2), G-local oscillator (105-2), G-PGA (106- 2), G-LPF (107-2), GSM RX B. B. Part (108-2) and a G-RSSI part (119-2).

  In addition, the transmission side is GSM TX B.B. B. Unit (109-2), GSM TX IQ unit (110-2), G-orthogonal modulation unit (111-2), G-local oscillator unit (112-2), and G-DRV (Driver Amplifier) (113-2), G-PA (114-2), ANT SW (115), and GSM transmitting / receiving antenna (101-2).

(GSM receiver side)
First, the GSM receiver side will be described.
On the GSM receiver side, a signal is received by the GSM transmitting / receiving antenna (111-2), and the received signal is input to the ANT SW (115). The ANT SW (115) inputs the input signal to the G-LNA (103-2), and amplifies the signal in the G-LNA (103-2).

  The G-LNA (103-2) inputs the amplified signal to the G-MIXER circuit (104-2), and the G-MIXER circuit (104-2) is input to the G-MIXER circuit (104-2). The G-local signal (105-2) having the same frequency as the received signal is mixed, and only the baseband signal is acquired from the signal input from the G-LNA (103-2).

  The G-MIXER circuit (104-2) inputs the acquired baseband signal to the G-PGA (106-2), and the W-PGA (106-2) receives the G-MIXER circuit (104-2). The G-LPF (107-2) inputs the signal input from the W-PGA (106-2) to the GSMLP B. B. Part (108-2).

  The G-PGA (106-2) inputs the signal input from the G-MIXER circuit (104-2) to the G-RSSI unit (119-2), and the G-RSSI unit (119-2) , G-PGA (106-2) detects the signal strength of the signal, and detects the detected signal strength as GSM RX B.B. B. Part (108-2).

(GSM transmitter side)
Next, the GSM transmission unit side will be described.
On the GSM transmitter side, GSM TX B. B. The GSM TX IQ unit (110-2) receives the IQ signal output from the unit (109-2), and the G-orthogonal modulation unit (111-2) receives the received IQ signal from the G-local signal (112- 2) to generate a transmission wave. The G-orthogonal modulation unit (111-2) inputs the generated transmission wave to a G-DRV (Driver Amplifier) (113-2).

  Since the G-DRV (113-2) is a variable gain amplifier, the transmission wave input from the G-orthogonal modulation unit (111-2) is amplified to a necessary output level, and the amplified transmission wave is amplified to G. -Input to PA (114-2).

  The G-PA (114-2) amplifies the transmission wave input from the G-DRV (113-2) to a level that can be output by the GSM transmission / reception antenna (101-2), and the amplified transmission signal is ANT. The signal is output to the SW (115), and the transmission signal is transmitted from the GSM transmitting / receiving antenna (101-2).

  Since the GSM system is a signal system in which the receiving unit side and the transmitting unit side do not operate at the same time, the ANT SW (115) includes the GSM transmitting / receiving antenna (101-2) and the G-LNA (103- 2), or the path of the connection between the GSM transmitting / receiving antenna (101-2) and the G-PA (114-2) is switched.

  Next, the processing operation in the compressed mode in the conventional communication terminal apparatus will be described with reference to FIGS.

  The communication terminal apparatus shown in FIG. 2 is a dual-mode compatible communication terminal apparatus of the W-CDMA system and the GSM system, and therefore needs to support handover from the W-CDMA system to the GSM system.

  For this reason, the communication terminal device itself is switched to the compressed mode, and the GSM peripheral level (reception level) is measured during a call using the W-CDMA system (during transmission / reception), and the line quality of the W-CDMA signal is measured. When it is determined that the GSM is deteriorated, it is determined whether or not the line quality of GSM is good. When it is determined that the line quality of GSM is good, the communication terminal apparatus controls to perform handover from the W-CDMA method to the GSM method, and makes a transition to a state in which communication is possible using the GSM method. Become.

  Note that the initial timing (3-1) shown in FIG. 3 indicates that the communication terminal apparatus is communicating with the W-CDMA system. For this reason, the communication terminal apparatus shown in FIG. B. Part (108-1) and WCDMA TX B.1. B. Section (109-1) operates and GSM RX B. B. Part (108-2) and GSM TX B.M. B. Control unit 109-2 is not operating. In such a state, since GSM communication is not performed, GSM TX B. B. Part (109-2) is controlled so as not to operate at all times.

  When measuring the peripheral level (reception level) of GSM during a call based on the W-CDMA system (during transmission / reception unit operation), the W-CDMA TX signal is compressed and the first timing (3-2) is measured. ) To the second timing (3-3) WCDMA TX B. B. A free time during which the section (109-1) is not operated, and the GSM RX B. B. The GSM signal is received by operating the unit (108-2).

  Note that WCDMA TX B.I. B. The reason why the unit (109-1) is not operated is to eliminate interference of GSM reception by the W-CDMA transmission wave. However, strictly speaking, GSM RX B.I. B. The unit (108-2) needs to be activated earlier than the first timing (3-2) by the amount of the lock time because of the relationship such as the lock time of the synthesizer circuit mounted in the terminal device.

  Note that the conventional communication terminal device needs to have two transmission / reception circuits so as to correspond to the two methods of the W-CDMA method and the GSM method, and this is a great adverse effect on downsizing the communication terminal device. It was.

  The communication terminal apparatus according to the present embodiment can use both communication systems (GSM system and W-CDMA system) with direct conversion, and can use a plurality of communication systems in exactly the same frequency band using existing base stations. The dual-mode compatible communication terminal device enables handover between a plurality of communication methods, and the communication terminal device can be miniaturized. It is.

  As shown in FIG. 1, in the communication terminal apparatus according to the present embodiment, the frequency of the W-CDMA system and the GSM system is the same on the receiving unit side, so the antenna (1) is a shared antenna. Also, DUP (2) and LNA (3) are shared.

  In addition, since the W-CDMA system and the GSM system do not operate simultaneously and are exclusive on the transmission unit side, the orthogonal modulation unit (12), DRV (13), and PA (14) are shared. However, since there is a high possibility that the standards of the transmission output level are different, it is necessary to perform transmission output control according to each transmission level.

  First, a configuration before the orthogonal modulation unit (12) on the transmission unit side will be described.

  As described above, the W-CDMA system and the GSM system do not operate at the same time and are exclusive operations as described above. B. Part (9-1) and GSM TX B. B. The unit (9-2) does not perform simultaneous operation.

  Therefore, at the time of W-CDMA communication, the communication mode changeover switch unit (11) connects the orthogonal modulation unit (12) and the WCDMA TX IQ unit (10-1) to connect the WCDMA TX B.B. B. The IQ signal output from the unit (9-1) is output as a transmission signal.

  Further, at the time of GSM communication, the communication mode changeover switch unit (11) connects the orthogonal modulation unit (12) and the GSM TX IQ unit (10-2), and the GSM TX B.B. B. The IQ signal output from the unit (9-2) is output as a transmission signal.

  Next, the configuration after the LNA (3) on the receiving unit side will be described.

  The reception signal amplified by the LNA (3) is distributed to the W-MIXER circuit (4-1) and the G-MIXER circuit (4-2).

  For this reason, the W-CDMA signal output from the W-MIXER circuit (4-1) is transmitted through the W-PGA (6-1) and the W-LPF (7-1). B. Is output to the section (8-1).

  The GSM signal output from the G-MIXER circuit (4-2) is transmitted through the G-PGA (6-2) and G-LPF (7-2). B. Part (8-2).

  Finally, the block configuration of the synthesizer circuit will be described.

  The communication terminal apparatus according to the present embodiment requires two different systems for the local oscillators (5-1, 5-2) on the receiving unit side in order to be able to cope with the compressed mode. This is referred to as W-local oscillator (5-1) and G-local oscillator (5-2).

  The W-local oscillator unit (5-1) and the G-local oscillator unit (5-2) are set to the reception frequency frequencies of the GSM system and the W-CDMA system, respectively, and are locked up. Each is input to the MIXER circuit (4-1, 4-2) and mixed with the received signal input from the LNA (3) in the MIXER circuit (4-1, 4-2) to extract a signal component. .

  Regarding the generation of the carrier on the transmission unit side, taking advantage of the fact that the transmission and reception bands of both the GSM system and the W-CDMA system are exactly the same, the IF Local unit (15), the carrier generation unit (16), the carrier buffer unit ( 17).

  Since the IF Local unit (15) has a constant interval between the transmission frequency and the reception frequency, the IF Local unit (15) may always be locked up to the difference frequency between the two. In addition, regarding power control, the power of the carrier wave generation unit (16) is always activated during communication, thereby changing the load of the W-station generator (5-1) and the G-station generator (5-2). Frequency fluctuation can be reduced.

  Next, the processing operation in the compressed mode in the communication terminal device of the present embodiment will be described with reference to FIGS.

  In the compressed mode in the 3GPP standard, it is defined only for the measurement of the GSM reception level during W-CDMA communication. B. The part (9-2) is always OFF.

  Therefore, GSM TX B. B. The IQ signal is not output from the section (9-2), and the GSM TX IQ section (10-2) is turned off. The communication mode changeover switch unit (11) connects between the orthogonal modulation unit (12) and the WCDMA TX IQ unit (10-1).

  First, the initial timing (3-1) shown in FIG. 3 indicates that communication is being performed by the W-CDMA system. Therefore, all of the W-CDMA RX circuit and the W-CDMA TX circuit are turned on, and all of the GSM RX circuits are turned off.

  Therefore, the G-MIXER circuit (4-2), G-local oscillator (5-2), G-PGA (6-2), G-LPF (7-2), G-RSSI unit (19) of FIG. -2), GSM RX B.I. B. The part (8-2) is turned off.

  Next, when measuring the reception level of the GSM system, at the first timing (3-2) for shifting to the compressed mode shown in FIG. GSM RX B. B. Part (8-2). As a result, all the GSM RX circuits are turned on (however, it is necessary to turn on the G-local oscillator (5-2) quickly in consideration of the lock time of the synthesizer circuit).

  At this time, since the received signal from the LNA (3) is distributed to the W-MIXER circuit (4-1) and the G-MIXER circuit (4-2), the load viewed from the LNA (3) varies. As a result, the signal level of the received signal input to each MIXER circuit (4-1, 4-2) decreases.

  Therefore, when the mode is shifted to the compressed mode, the compressed mode shift signal generator (18) outputs the compressed mode shift signal, and the W-MIXER circuit (4-1) and the G-MIXER circuit (4- The gain of 2) is increased, and control is performed so that the received signal is the same as in the single connection. As a result, even when the mode is shifted to the compressed mode, reception signals having the same level as that in the single connection are input to the W-PGA (6-1) and the G-PGA (6-2), respectively.

  Note that when the mode is shifted to the compressed mode, it is necessary to measure the GSM reception level during W-CDMA communication. However, as shown in FIG. 1, the communication terminal device according to the present embodiment collects reception circuits such as LNA (3) in one system, so that W-PGA (6-1), G-PGA ( In 6-2), a mixed signal of a W-CDMA reception signal and a GSM reception signal is input.

  For this reason, when the communication terminal apparatus in this embodiment shifts to the compressed mode and generates a compressed mode shift signal, the output voltage obtained from the G-RSSI unit (19-2) is set to the GSM RSSI level. When converting, an accurate GSM RSSI level can be measured by performing an offset process of subtracting the W-CDMA RSSI level obtained from the W-RSSI unit (19-1).

  Finally, at the second timing (3-3) when the measurement of the GSM reception level is completed and the communication mode returns to the mode in communication with the W-CDMA system again, the compressed mode transition signal is not generated and the compressed mode is not generated. The mode transition signal is turned off. As a result, similar to the initial timing, the GSM RX circuit returns to the OFF state, and the G-MIXER circuit (4-2), G-local oscillator (5-2), G-PGA (6- 2), G-LPF (7-2), G-RSSI section (19-2), and GSM RX B. B. The part (8-2) is in the OFF state.

  As described above, the communication terminal apparatus according to the present embodiment is a communication terminal apparatus that can support two different communication systems (GSM system and W-CDMA system). It is possible to reduce the size of the communication terminal device by sharing with the W-CDMA system.

  Also, the communication terminal device in the present embodiment generates a compressed mode transition signal when shifting to the compressed mode, and controls gain switching of the MIXER circuit (4-1, 4-2) or GSM. By controlling so as to reduce the influence of the W-CDMA system when measuring the reception level of the system, it is possible to cope with a handover from the W-CDMA system to the GSM system.

(Second Embodiment)
Next, a second embodiment will be described.
The communication terminal apparatus according to the second embodiment is characterized in that a reception antenna and a transmission antenna are individually provided. As a result, the communication terminal apparatus in the second embodiment can further improve power saving and reception sensitivity. Hereinafter, the communication terminal apparatus according to the second embodiment will be described with reference to FIG. FIG. 4 shows the internal configuration of the dual-mode compatible communication terminal apparatus in the second embodiment.

  The communication terminal device according to the second embodiment is different from FIG. 1 in that the transmission / reception antenna (1) is separated into a reception antenna (1-1) and a transmission antenna (1-2). As a result, it is possible to improve power saving and reception sensitivity while maintaining the degree of circuit integration.

  The communication terminal device according to the first embodiment is configured to input the transmission signal and the reception signal to the DUP (2) and connect to the transmission / reception antenna (1). However, the insertion loss of the DUP (2) is low. If it is large, there is a concern that the reception sensitivity is deteriorated from the viewpoint of reception characteristics. Moreover, even from the viewpoint of transmission characteristics, there is a concern about an increase in power consumption due to transmission power loss.

  For this reason, the communication terminal device according to the second embodiment provides the reception antenna (1-1) and the transmission antenna (1-2) separately, thereby providing the reception antenna (1-1). Therefore, it is possible to ensure isolation between the transmitting antenna (1-2) and the power consumption and the reception sensitivity can be improved.

  The above-described embodiment is a preferred embodiment of the present invention, and the scope of the present invention is not limited to the above-described embodiment alone, and various modifications are made without departing from the gist of the present invention. Implementation is possible.

  The communication terminal device according to the present invention can be applied to a service network of a mobile phone carrier that supports a plurality of communication methods in the same frequency band or in close frequency bands.

It is a figure which shows the internal structure of the communication terminal device in this embodiment. It is a figure which shows the internal structure of the conventional communication terminal device. It is a figure which shows the operation timing in a communication terminal device. It is a figure which shows the internal structure of the communication terminal device in 2nd Embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Transmission / reception antenna 1-1 Transmission antenna 1-2 Reception antenna 2 DUP (Duplexer)
3 LNA (Low Noise Amplifier)
4 MIXER circuit 5 Local oscillator 6 PGA (Programmable Gain Amplifier)
7 LPF
8 RX B.E. B. Part 9 TX B.B. B. Unit 10 TX IQ unit 11 path changeover switch 12 quadrature modulation unit 13 DRV (Driver Amplifier)
14 PA (Power Amplifier)
15 IF Local part 16 Carrier wave generating part 17 Carrier wave buffer part 18 Compressed mode transition signal generating part 19 RSSI part

Claims (20)

A communication terminal device applicable to a plurality of wireless communication systems,
Receiving means and transmitting means applicable to the plurality of wireless communication systems;
Communication means for controlling the receiving means and the transmitting means, and performing handover between the plurality of wireless communication systems;
A communication terminal device comprising:   The communication terminal apparatus according to claim 1, wherein the receiving unit is a direct conversion system. The receiving means includes
An antenna for receiving a received signal;
Separating means for separating the received signal received by the antenna into signals corresponding to a plurality of wireless communication systems;
Control means for controlling the signal separated by the separation means using a wireless communication method corresponding to the signal;
The communication terminal apparatus according to claim 1, further comprising: The transmission means includes
Transmission signal generating means for generating a transmission signal corresponding to a plurality of wireless communication systems;
An antenna for transmitting the transmission signal generated by the transmission signal generating means;
The communication terminal device according to any one of claims 1 to 3, wherein the communication terminal device includes:   5. The communication terminal apparatus according to claim 4, wherein the antenna of the receiving unit and the antenna of the transmitting unit are a common antenna.   The communication terminal apparatus according to claim 4, wherein the antenna of the receiving unit and the antenna of the transmitting unit are different antennas. The control means includes
Signal component acquisition means for mixing a local oscillation signal having the same frequency as the signal separated by the separation means and obtaining a baseband signal from the signal;
Signal strength detection means for detecting the signal strength of the signal separated by the separation means;
Have
The control means uses the baseband signal acquired by the signal component acquisition means and the signal intensity detected by the signal intensity detection means to convert the signal separated by the separation means to a radio corresponding to the signal. 4. The communication terminal apparatus according to claim 3, wherein control is performed using a signal system.   8. The communication terminal apparatus according to claim 7, further comprising a local signal generator that generates the local signal.   9. The communication terminal apparatus according to claim 8, wherein the transmission signal generation unit generates the transmission signal using the local signal generated by the local signal generation unit. The communication means includes
2. The communication terminal apparatus according to claim 1, wherein at the time of transition to the compressed mode, the reception unit and the transmission unit are controlled to perform handover between the plurality of wireless communication systems. A communication method performed in a communication terminal device applicable to a plurality of wireless communication methods,
A receiving process for receiving a received signal;
A control step of controlling the received signal received by the receiving step using a wireless communication method corresponding to the received signal;
A handover step of switching from a wireless communication system corresponding to the received signal to a different wireless communication system;
The communication terminal device performs the communication method.   The communication method according to claim 11, wherein the reception step is performed by a direct conversion method. The communication terminal device performs a separation step of separating the reception signal received in the reception step into signals corresponding to a plurality of wireless communication systems,
The control step includes
The communication method according to claim 11 or 12, wherein the signal separated by the separation step is controlled using a wireless communication method corresponding to the signal. A transmission signal generation step of generating a transmission signal corresponding to a plurality of wireless communication systems;
A transmission step of transmitting the transmission signal generated by the transmission signal generation step;
The communication method according to claim 11, wherein the communication terminal device performs the following.   The communication method according to claim 14, wherein the reception step and the transmission step are performed by a common antenna.   The communication method according to claim 14, wherein the reception step and the transmission step are performed by different antennas. A signal component acquisition step of mixing a local oscillation signal having the same frequency as the signal separated by the separation step and obtaining a baseband signal from the signal separated by the separation step;
A signal strength detection step of detecting the signal strength of the signal separated by the separation step;
Is performed by the communication terminal device,
The control step includes
Using the baseband signal acquired by the signal component acquisition step and the signal intensity detected by the signal strength detection step, the signal separated by the separation step is converted using a radio signal system corresponding to the signal. 14. The communication method according to claim 13, wherein the communication method is controlled. A local signal generating step for generating the local signal,
The communication method according to claim 17, wherein the communication terminal device performs the communication method. The transmission signal generation step includes
19. The communication method according to claim 18, wherein the transmission signal is generated using the local signal generated in the local signal generation step. The handover step includes
The communication method according to claim 11, wherein the communication method is performed when the compressed mode is entered.

Images