JP3751205B2 - Communication device and communication control method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a communication device and a communication control method, and more particularly, to a communication device having a communication function corresponding to two different wireless communication systems, and a communication control method for controlling the communication operation.
[0002]
[Prior art]
In recent years, a wireless communication standard called Bluetooth has been developed. The bluetooth standard is a communication standard for performing wireless communication between a plurality of electronic devices within a few meters using a radio signal having a frequency of 2.4 GHz band.
Electronic devices equipped with a wireless communication unit conforming to the bluetooth standard form a small network called a piconet and can communicate with each other between electronic devices belonging to the same piconet. Also, one electronic device can belong to a plurality of piconets at the same time.
For this reason, it has been attracting attention as a communication method for connecting various devices such as mobile phone terminals, personal computers, peripheral devices, and music players.
[0003]
For example, a PDC (Personal Digital Cellular) mobile phone is equipped with a communication circuit conforming to the bluetooth standard, and while performing main communication (use as a mobile phone) by the PDC method with the various electronic devices, A usage pattern such as bluetooth communication is conceivable.
[0004]
FIG. 5 is a block diagram showing a conventional configuration of a communication unit 100 of a PDC mobile phone incorporating a communication circuit conforming to the bluetooth standard.
As illustrated in FIG. 5, the communication unit 100 includes a PDC transmission / reception circuit (a PDC reception circuit 111, a PDC transmission circuit 112, an antenna switch 113, an antenna ANT1, ANT2), a bluetooth transmission / reception circuit (PDC reception circuit 121, PDC transmission circuit 122, antenna switch 123, antenna ANT3) for transmitting / receiving a bluetooth signal (hereinafter referred to as a bluetooth signal), a baseband unit 4, Is provided.
[0005]
Diversity control is performed in a TDMA communication device used in the PDC method as a fading countermeasure. Here, the example which employ | adopted the antenna switching diversity system is shown.
That is, two antennas ANT1 and ANT2 are provided, and the antennas ANT1 and ANT2 are connected to the antenna switch 113, and the antenna switch 113 uses the antenna having the better reception state of the two antennas ANT1 and ANT2. Switch as follows. This switching operation is controlled by the baseband unit 4.
[0006]
In addition, in order to mount a wireless communication function conforming to the bluetooth standard, normally, apart from the antennas ANT1 and ANT2 for PDC reception, at least one antenna, one system transmission circuit, one system reception circuit, It is necessary to have.
That is, the bluetooth transmission / reception circuit includes a bluetooth reception circuit 121, a bluetooth transmission circuit 122, an antenna switch 123, and an antenna ANT3.
The antenna switch 123 is a switch that switches the antenna ANT3 to the bluetooth reception circuit 121 side or the bluetooth transmission circuit 122 side, and the switching operation is controlled by the baseband unit 4.
[0007]
As described above, when a wireless communication unit conforming to the bluetooth standard is incorporated into a communication device such as a mobile phone, a transmission / reception circuit for main communication, that is, a PDC transmission / reception circuit in the above example, and another bluetooth The transmission / reception circuit of the system is incorporated independently.
When a diversity function is installed in order to improve the reception characteristics of the bluetooth signal, two antennas, one transmission circuit, and two reception circuits are necessary as a bluetooth transmission / reception circuit.
[0008]
[Problems to be solved by the invention]
However, in the conventional communication device incorporating a communication circuit of another communication method (bluetooth method or the like) different from the main communication circuit (PDC method) as described above, other communication methods are used in order to reduce the size of the device. There was a tendency to limit the circuit configuration of (bluetooth method).
[0009]
That is, the configuration for performing diversity on the other communication system (bluetooth system) side tends to be omitted. Therefore, when receiving a signal of another communication method (bluetooth method), characteristic deterioration due to fading is likely to occur, and stable communication operation is hindered.
[0010]
An object of the present invention is to provide a communication device including a communication circuit corresponding to a different wireless communication method in addition to the main communication circuit, with a simple circuit configuration and stable in a communication circuit of another wireless communication method. A communication apparatus capable of performing a communication operation and a communication control method are provided.
[0011]
[Means for Solving the Problems]
  In order to solve such a problem, the invention of claim 1
A first receiving circuit (for example, the PDC shown in FIG. 1) that receives a first radio signal corresponding to a first communication method (for example, PDC communication method) that repeatedly performs a receiving operation and a non-receiving operation at a predetermined time interval. A receiving circuit 11);
A second communication method different from the first communication method (for example, bluetooth A second receiving circuit (for example, shown in FIG. 1) that receives a second wireless signal corresponding to a standard (a wireless communication system conforming to the standard) bluetooth Receiving circuit 21);
A third receiving circuit (for example, shown in FIG. 1) that is different from the second receiving circuit that receives the second radio signal by sharing at least a part of the first receiving circuit. bluetooth Receiving circuit 31);
During the reception operation in the second reception circuit and during the non-reception operation in the first reception circuit (for example, (1) in FIG. 3C), the second reception circuit performs the second operation. Switching control means (for example, the baseband unit 4 and the switch SW1 shown in FIG. 1, steps S1 to S3 → S4 in FIG. 4) for switching to receive the wireless signal of
Reception status determination means (for example, the baseband unit 4 shown in FIG. 1, steps S2 and S4 in FIG. 4) for determining the reception status in the second and third reception circuits;
Diversity control means (for example, the baseband unit 4 shown in FIG. 1 and step S4 in FIG. 4) for executing and controlling diversity for the second radio signal using the second and third receiving circuits;
With
The diversity control means controls execution of diversity for the second radio signal according to a determination result by the reception status determination means during a non-reception operation in the first reception circuit.
[0012]
Here, the diversity control means may employ a post-detection selection diversity system as a diversity system for the second radio signal, or may employ a received wave synthesis diversity system.
[0013]
Further, the non-reception operation in the first reception circuit includes, for example, a non-reception slot ((1) in FIG. 3C) during standby of the first radio signal or communication operation.
[0014]
Also, the reception status determination result may be obtained by comparing the received electric field strength (RSSI) with a predetermined threshold, or may be obtained by comparing the bit error rate of the received signal with a predetermined threshold. .
[0015]
According to the first aspect of the invention, apart from the second receiving circuit, a part of the first receiving circuit that receives the first wireless signal is shared to receive the second wireless signal. Since the receiving circuit is provided, two systems of receiving circuits for the second radio signal can be provided with a simple configuration. In addition, since the diversity control means executes the diversity for the second signal using the two receiving circuits (second and third) during the non-receiving operation in the first receiving circuit, The reception characteristic of the second radio signal can be improved while the circuit configuration of the entire apparatus is minimized, and a stable communication operation can be performed. Further, the switching control means automatically causes the third receiving circuit to receive the second radio signal during the receiving operation in the second receiving circuit and during the non-receiving operation in the first receiving circuit. Therefore, the diversity for the second radio signal can be executed in this section, and the reception characteristic of the second radio signal can be improved without disturbing the reception of the first radio signal. In addition, the reception status determination means determines the reception status in the second receiving circuit, and executes diversity for the second radio signal according to the determination result. If the reception status is good, the second radio Since it is not necessary to perform diversity on the signal, appropriate diversity control can be performed.
[0016]
  The invention according to claim 2 is the communication apparatus according to claim 1,
  The reception status determination means further determines a reception status in the first reception circuit,
  The diversity control means executes diversity for the first radio signal using the first reception circuit according to a determination result by the reception status determination means during a reception operation in the first reception circuit. It is characterized by control.
[0017]
According to the second aspect of the present invention, the diversity control means executes diversity for the first signal using the first receiving circuit during the receiving operation in the first receiving circuit. The reception characteristic of one radio signal can be improved, and a stable communication operation can be performed.
[0018]
  The invention according to claim 3 is the communication apparatus according to claim 1 or 2, wherein
The first and third receiving circuits share at least an antenna (for example, the antenna ANT1 or ANT2 shown in FIG. 1),
The first receiving circuit includes a filter group (for example, including BPF 11a and BPF 11c shown in FIG. 1) that extracts the first radio signal from the received signal at the antenna.
The third receiving circuit includes a filter group (for example, including BPF 31a and BPF 31b shown in FIG. 1) that extracts the second radio signal from the received signal at the antenna.
The second receiving circuit is a filter group (for example, BPF 21a shown in FIG. 1) that extracts the second radio signal from a received signal in a second antenna (for example, antenna ANT3 shown in FIG. 1) different from the antenna. And BPF21b).
[0019]
  According to the third aspect of the present invention, the first and third receiving circuits share the antenna, the first receiving circuit extracts the first radio signal from the received signal at the antenna, and the third receiving circuit Then, the second radio signal can be extracted, and the second receiving circuit can receive the second radio signal with an antenna different from the antenna. Therefore, the second radio signal is received from two different antennas. Diversity can be executed. Further, since a large-scale configuration such as an antenna can be shared by the first and third receiving circuits, the apparatus can be reduced in size.
[0020]
Invention of Claim 4 is a communication apparatus as described in any one of Claims 1-3,
The first and third receiving circuits further share a power amplifier (for example, LNA 11b shown in FIG. 1).
[0021]
According to the invention of claim 4, since the first and third receiving circuits further share the power amplifier, the apparatus can be further downsized.
[0022]
Moreover, in the communication device according to any one of claims 1 to 4, as in the invention according to claim 5,
The first communication method is a mobile phone communication method (for example, PDC method),
The second communication method is, for example, bluetooth It is desirable to adopt a wireless communication system conforming to the standard.
[0023]
According to invention of Claim 5, bluetooth Applying to mobile phones with built-in wireless communication functions according to the standard, while keeping the mobile phone terminal small, bluetooth Communication quality of wireless communication according to the standard can be improved.
[0024]
The invention described in claim 6
A first receiving circuit (for example, the PDC receiving circuit 11 shown in FIG. 1) that receives a first radio signal corresponding to a first communication method that repeatedly performs a receiving operation and a non-receiving operation at a predetermined time interval;
A second receiving circuit (for example, shown in FIG. 1) that receives a second radio signal corresponding to a second communication method different from the first communication method bluetooth Receiving circuit 21);
A third receiving circuit (for example, shown in FIG. 1) that is different from the second receiving circuit that receives the second radio signal by sharing at least a part of the first receiving circuit. bluetooth Receiving circuit 31);
A communication control method in a communication device comprising:
A switching control step of switching to receive the second radio signal in the third receiving circuit during a receiving operation in the second receiving circuit and a non-receiving operation in the first receiving circuit ( For example, steps S1 to S3 → S4 in FIG.
A reception status determination step (for example, step S4 in FIG. 4) for determining the reception status in the second and third reception circuits;
A diversity control step (for example, step S4 in FIG. 4) for executing and controlling diversity for the second radio signal using the second and third receiving circuits;
Including
In the diversity control step, during the non-reception operation in the first reception circuit, the diversity of the second radio signal is executed and controlled according to the determination result in the reception state determination step.
[0025]
According to the sixth aspect of the invention, apart from the second receiving circuit, a part of the first receiving circuit that receives the first wireless signal is shared to receive the second wireless signal. In order to control the communication operation in the communication device including the receiving circuit, the third receiving circuit is in the receiving operation in the second receiving circuit and in the non-receiving operation in the first receiving circuit. The second radio signal is switched to be received, and the second and third receiving circuits are used to execute and control diversity for the second radio signal. In addition, since the reception situation in the second reception circuit is determined and it is determined whether or not to perform diversity for the second radio signal according to the determination result, the reception situation in the one reception circuit is good. Then, since it is not necessary to perform diversity for the second radio signal, appropriate diversity control can be performed.
[0026]
Therefore, during the reception operation in the second reception circuit and the non-reception operation in the first reception circuit, the third reception circuit automatically switches to receive the second radio signal, and this section Since the second wireless signal is received by the two-system (second and third) receiving circuits in FIG. 1, diversity for the second wireless signal can be executed. Therefore, the reception characteristic of the second radio signal can be improved, and a stable communication operation can be performed.
[0027]
The invention according to claim 7 is the communication control method according to claim 6,
The reception status determination step further determines a reception status in the first reception circuit,
  The diversity control step executes diversity for the first radio signal using the first reception circuit according to a determination result in the reception state determination step during a reception operation in the first reception circuit. It is characterized by control.
[0028]
According to the seventh aspect of the present invention, the diversity control means executes diversity for the first signal using the first receiving circuit during the receiving operation in the first receiving circuit. The reception characteristic of one radio signal can be improved, and a stable communication operation can be performed.
[0031]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of a communication apparatus according to the present invention will be described in detail with reference to the drawings.
[0032]
First, the configuration will be described.
FIG. 1 is a block diagram illustrating a configuration of a communication device 10 according to the present embodiment.
As shown in FIG. 1, the communication device 10 transmits and receives radio signals based on the PDC communication system, and a PDC transmission / reception circuit (PDC reception circuit 11, PDC transmission circuit 12, antenna) that shares part of it with the bluetooth reception circuit. ANT1, ANT2, and antenna switcher 13), a transmitter / receiver circuit (bluetooth receiver circuit 21, bluetooth transmitter circuit 22, antenna ANT3, antenna switcher 23), and PDC receiver circuit for transmitting and receiving radio signals based on the Bluetooth communication system 11 is configured to include a bluetooth receiving circuit 31 configured to share a part of the mobile terminal 11 and the baseband unit 4.
[0033]
That is, the communication device 10 is equipped with a function for transmitting / receiving a radio signal based on the PDC communication system as a main communication and a function for transmitting / receiving a radio signal based on a wireless communication system based on the Bluetooth standard.
In the following description, the PDC communication method is referred to as “PDC method”, and the communication method conforming to the bluetooth standard is referred to as “bluetooth method”. Further, a signal transmitted / received based on the PDC method is referred to as a “PDC signal”, and a signal transmitted / received based on the bluetooth method is referred to as a “bluetooth signal”.
[0034]
First, the PDC transmission / reception circuit will be described.
As shown in FIG. 1, the PDC transmission / reception circuit includes a PDC reception circuit 11, a PDC transmission circuit 12, antennas ANT1 and ANT2, and an antenna switch 13.
[0035]
The antennas ANT1 and ANT2 are connected to the PDC reception circuit 11 and the PDC transmission circuit 12 via the antenna switch 13.
The antenna switch 13 switches the antenna to be used among the antennas ANT1 and ANT2 based on the antenna switching control signal supplied from the baseband unit 4. Specifically, the antenna ANT1 is switched during the transmission operation, and the antenna switching diversity is executed during the reception operation, so that the antenna ANT1 or ANT2 is switched to the antenna having the better reception status.
[0036]
The PDC reception circuit 11 includes a BPF (bandpass filter) 11a, a BPF 31a, a switch SW1, an LNA (low noise amplifier) 11b, a BPF 11c, a BPF 31b, a MIX (mixer) 11d, a BPF 11e, and an IF IC 11f. Among these, the BPF 31a, the LNA (low noise amplifier) 11b, and the BPF 31b are configured to extract a bluetooth signal from a signal received by the antenna ANT1 or ANT2.
[0037]
The RF signal received by the antenna ANT1 or ANT2 is input to the BPF (band pass filter) 11a and the BPF 31a via the antenna switch 13.
The BPF 11a limits the band of the RF signal to the frequency of the PDC signal. The BPF 31a limits the band of the RF signal to the frequency of the bluetooth signal. Output signals from these BPFs 11a and 31a are input to the switch SW1.
[0038]
The switch SW1 is a changeover switch for selecting one of the output signals of the BPF 11a or BPF 31a and supplying the selected signal to the LNA 11b. In the PDC signal reception slot, the switch SW1 is switched to the BPF 11a side, and the PDC signal non-reception slot Then, it is switched to the BPF 31a side. In addition, it is switched to the BPF 31a side while waiting for PDC. The switching operation of the switch SW1 is controlled by the baseband unit 4.
[0039]
The LNA (low noise amplifier) 11b amplifies the signal selected by the switch SW1 and supplies the amplified signal to the BPF 11c and the BPF 31b.
The BPF 11c band-limits the signal amplified by the LNA 11b to the frequency of the PDC signal and supplies the signal to the MIX (mixer) 11d.
Further, the BPF 31 b limits the band of the signal amplified by the LNA 11 b to the frequency of the bluetooth signal and supplies it to the bluetooth receiving circuit 31.
[0040]
The MIX 11d mixes the signal supplied from the local transmitter 14 with the signal output from the BPF 11c, and down-converts the signal.
The BPF 11e limits the band of the signal down-converted by the MIX 11d and supplies it to the IF IC 11f.
The IF IC 11f down-converts the signal input from the BPF 11e with the signal supplied from the local transmitter 16, generates an intermediate frequency signal (IF signal) and outputs it to the baseband unit 4, and at the antenna ANT1 or ANT2 The received electric field strength (RSSI) of the received signal is detected and output to the baseband unit 4 as an RSSI signal.
[0041]
In the PDC reception circuit 11 configured as described above, when receiving a PDC signal (PDC signal reception slot), the switch SW1 is connected to the BPF 11a side. That is, the RF signal received by the antenna ANT1 or ANT2 is band-limited to the frequency of the PDC by the BPF 11a and the switch SW1, is input to the LNA 11b and amplified, and further, the frequency component of the PDC signal is extracted by the BPF 11c, and is extracted by the mixer 11d. The frequency signal supplied from the local oscillator 14 is mixed and down-converted. An IF signal is generated from the down-converted signal by the BPF 11e and the IF IC 11f and supplied to the baseband unit 4.
[0042]
In the non-reception slot of the PDC signal in the PDC reception circuit 11, the switch SW1 is switched to the BPF 31a side. That is, the RF signal received by the antenna ANT1 or ANT2 is band-limited to the bluetooth frequency by the BPF 31a and the switch SW1, input to the LNA 11b and amplified, and further, the frequency component of the bluetooth signal is extracted by the BPF 31b. The output of the BPF 31b branches from the PDC receiving circuit 11, is input to the bluetooth receiving circuit 31, and is supplied to the detector 31c.
[0043]
The PDC transmission circuit 12 includes a modulator 12a, a BPF 12b, a MIX 12c, a BPF 12d, an amplifier (AMP) 12e, and an LPF (low-pass filter) 12f.
The I and Q signals supplied from the baseband unit 4 are input to the modulator 12a, and π / 4 shift 4-phase QPSK modulation is performed by the signal supplied from the local oscillator 15 by the modulator 12a, and is modulated by the modulator 12a. The signal is band-limited by the BPF 12b and mixed with the signal supplied from the local oscillator 14 by the MIX 12c. Further, necessary frequency components are extracted by the BPF 12d, the amplifier 12e, and the LPF 12f, power amplified, and transmitted from the antenna ANT1 or ANT2 via the antenna switch 13.
[0044]
Next, the bluetooth transmission / reception circuit will be described.
The bluetooth transmission / reception circuit includes a part of the circuit configuration of the bluetooth reception circuit 21 and the bluetooth transmission circuit 22 connected to the antenna ANT3 via the antenna switch 23, the antenna switch 13, the antennas ANT1, ANT2, and the LNA 11b. It is comprised by the bluetooth receiving circuit 31 shared with the receiving circuit 11. FIG. That is, a total of three antennas, two bluetooth reception circuits, and one bluetooth transmission circuit are provided.
[0045]
The antenna ANT3 is connected to either the bluetooth reception circuit 21 or the bluetooth transmission circuit 22 via the antenna switch 23.
Based on the antenna switching control signal supplied from the baseband unit 4, the antenna switch 23 switches the antenna ANT3 to the bluetooth receiving circuit 21 during the receiving operation and switches to the bluetooth transmitting circuit 22 during the transmitting operation.
[0046]
The bluetooth receiving circuit 21 includes a BPF 21a, an LNA 21b, a BPF 21c, and a detector 21d.
The RF signal received by the antenna ANT3 is input to the BPF 21a via the antenna switch 23. The BPF 21a limits the band of the RF signal to the frequency of the bluetooth signal, and supplies it to the LNA 21b. The LNA 21b amplifies the output signal from the BPF 21a and supplies it to the BPF 21c. The BPF 21c extracts the frequency component of the bluetooth signal from the signal amplified by the LNA 21b and supplies it to the detector 21d. The detector 21 d detects the extracted bluetooth signal based on the signal supplied from the local transmitter 22 a of the bluetooth transmission circuit 22, and supplies the I and Q signals as detection outputs to the baseband unit 4. The detector 21d detects the received electric field strength (RSSI) of the signal received by the antenna ANT3, and outputs it to the baseband unit 4 as an RSSI signal.
[0047]
The bluetooth transmission circuit 22 includes a local transmitter 22a, a BPF 22b, an AMP 22c, and an LPF 22d. The local transmitter 22a supplies a signal having a predetermined frequency to the BPF 22b based on the transmission data supplied from the baseband unit 4. The BPF 22b, the amplifier 22c, and the LPF 22d limit the signal band, amplify the power, and transmit the signal from the antenna ANT3 via the antenna switch 23.
[0048]
The bluetooth receiving circuit 31 includes a detector 31c provided separately from the bluetooth receiving circuit 21, and BPF 31a, LNA 11b, and BPF 31b included in the PDC receiving circuit 11.
[0049]
That is, the bluetooth receiving circuit 31 shares the antennas ANT1 and ANT2 with the PDC receiving circuit 11, and also shares the LNA 11b included in the PDC receiving circuit 11. The BPF 31a, the switch SW1, and the BPF 31b included in the PDC receiving circuit 11 function as a filter group for extracting a bluetooth signal from the RF signal received by the antenna ANT1 or ANT2.
When the bluetooth signal is received by the bluetooth reception circuit 31, the switch SW1 of the PDC reception circuit 11 is switched to the BPF 31a side by the switch switching control signal from the baseband unit 4.
[0050]
The RF signal received by the antenna ANT1 or ANT2 and input to the PDC receiving circuit 11 via the antenna switch 13 is first input to the BPF 11a and the BPF 31a. However, since the switch SW1 is switched to the BPF 31a side, the bluetooth is transmitted. A signal limited to the frequency band of the signal is selected and supplied to the LNA 11b. The LNA 11b amplifies the signal and supplies it to the BPF 11c and the BPF 31b. Then, the signal band-limited to the frequency of the bluetooth signal by the BPF 31b is supplied to the detector 31c of the bluetooth receiving circuit 31.
[0051]
The detector 31c detects the signal supplied from the BPF 31b of the PDC receiving circuit 11 based on the signal supplied from the local transmitter 22a of the bluetooth transmission circuit 22, and bases the I and Q signals which are the detection outputs. 4 is output. Moreover, the detector 31c detects the received electric field strength (RSSI) of the signal received by the antennas ANT1 and ANT2, and outputs the detected signal to the baseband unit 4 as an RSSI signal.
[0052]
Here, transmission / reception timing in bluetooth communication will be described with reference to FIG.
A plurality of electronic devices equipped with a bluetooth communication circuit form a small network called a piconet. In a piconet, one master and up to seven slaves can communicate. Therefore, in order for them to communicate, all electronic devices are synchronized on the frequency axis and the time axis. When there are a plurality of slaves in the same piconet, the slave and master communication paths are shared by all the slaves while being time-division multiplexed. The unit of time division multiplexing is a time interval of 625 μsec called a time slot.
[0053]
FIG. 2 shows packet transmission / reception timings when a piconet is formed by an electronic device equipped with the communication circuit 10 and another electronic device having a bluetooth communication function, and one is a master and the other is a slave. Is shown.
“F (2k)” shown in FIG. 2 means the transmission frequency of the master in the slot number “2k (even number)”, and “f (2k + 1)” means the slave in the slot number “2k + 1 (odd number)”. It means transmission frequency.
[0054]
As shown in FIG. 2, when the slot number is an even number, ie, “2k”, “2k + 2”,..., Packets are transmitted from the master to the slave in the same piconet. Is done. When the slot number is an odd number, that is, “2k + 1”, “2k + 3”,..., Packets are transmitted from the slave to the master.
Only the slave that has received a packet from the master in the even slot can transmit the packet to the master in the odd slot. The odd slot in which the slave transmits the packet is only in the odd slot “2k + 1” immediately after the even slot “2k” that received the packet, and transmission is prohibited in the other odd slots.
[0055]
The baseband unit 4 controls transmission / reception operations based on the PDC method and transmission / reception operations based on the bluetooth method, and processes signals and data to be transmitted and received.
For example, as processing for PDC transmission / reception, various processing such as π / 4QPSK modulation / demodulation processing, TDMA processing, voice processing, error correction, and the like are performed. As processing for bluetooth transmission / reception, communication link provision, transmission / reception frequency designation / switching processing for managing frequency hopping, time axis slot management processing, packet retransmission processing, error correction processing, and the like are performed.
[0056]
Further, the baseband unit 4 controls the switch SW1 to switch to the BPF 11a side in the PDC reception slot so that the PDC reception circuit 11 performs the reception operation of the PDC signal, and the PDC transmission slot performs the transmission operation in the PDC transmission circuit 12. (See FIGS. 3A and 3B). In addition, the communication device 1 according to the present embodiment compares the RSSI values of the received signals supplied from the antennas ANT1 and ANT2 in order to execute antenna switching diversity in the PDC reception operation, and selects the antenna having the larger RSSI value. The antenna switch 13 is controlled to select, and the antenna to be used is switched.
[0057]
The baseband unit 4 controls the diversity operation for the bluetooth signal. That is, the baseband unit 4 executes diversity control processing (see FIG. 4), and determines the reception status based on the RSSI signal measured in the bluetooth receiving circuit 21 during the bluetooth communication operation. If the RSSI value is larger than the predetermined threshold (XdB), the reception status is good, and therefore, the diversity for the bluetooth signal is not executed.
[0058]
On the other hand, if the reception status of the bluetooth reception circuit 21 is not good, that is, if the RSSI value is equal to or less than the predetermined threshold (XdB), it is further determined whether or not it is a PDC reception slot in the PDC reception circuit 11, In the slot ((1) in FIG. 3C), the bluetooth signal diversity operation is performed, and in the PDC reception slot ((2) in FIG. 3 (C)), the bluetooth signal diversity operation is not performed. That is, in the PDC non-reception slot, the switch SW1 is switched to the BPF 31a side to extract the bluetooth signal from the reception signal at the antenna ANT1 or ANT2, and the bluetooth reception circuit 31 detects the received signal and the reception signal at the antenna ANT3 to the bluetooth reception circuit 21. Diversity operation is performed using the detection outputs from the two bluetooth receiving circuits 21 and 31.
[0059]
Here, the diversity method for the bluetooth signal may be a post-detection selection diversity method or a received wave combining diversity method.
[0060]
When the post-detection selection diversity method is adopted, the baseband unit 4 selects one of the bluetooth signals received by the bluetooth receiving circuit 21 and the bluetooth receiving circuit 31 that has a better reception state. For the determination of the reception status, the values of the RSSI signals supplied from the receiving circuits 31 and 21 are compared, and the detection output with the larger RSSI value is determined to have a good reception level.
[0061]
When the received wave combining diversity method is adopted, the baseband unit 4 receives the antenna signal ANT1 when each blue and blue signal is output from the bluetooth receiving circuit 21 and the bluetooth receiving circuit 31. Alternatively, arithmetic processing is performed so that a delay time difference between the signal reaching ANT2 and the signal reaching antenna ANT3 is eliminated, and the above I and Q signals are combined.
In the received wave combining diversity method, since received waves are combined, received signal energy can be used without waste, and better diversity can be achieved.
[0062]
Next, the operation will be described.
First, the relationship between the transmission / reception timing of the PDC signal and the diversity operation timing for the bluetooth signal in the communication apparatus 10 according to the present embodiment will be described with reference to FIG.
[0063]
As shown in FIG. 3A, the PDC transmission circuit 12 performs a transmission operation in a 20/3 ms transmission slot, and then sets a certain time as a non-transmission slot.
As shown in FIG. 3B, the PDC reception circuit 11 sets 20/3 ms after the transmission slot as a reception slot, and performs a reception operation in this reception slot. After that, a certain time is set as a non-reception slot.
[0064]
In this embodiment, as shown in FIG. 3 (C), the PDC receiving circuit 11 does not receive the PDC signal (the section (1), that is, the non-receiving slot). The receiver circuits 21 and 31 are operated to execute the bluetooth signal diversity. During reception of the PDC signal (section (2), that is, the reception slot), the bluetooth signal diversity is not executed. Perform receive operation.
Therefore, the baseband unit 4 switches the switch SW1 to the BPF 11a side in the reception slot ({circle around (2)}) and switches to the BPF 31a side in the non-reception slot ({circle around (1)}).
[0065]
In order to execute the diversity operation for the bluetooth signal at the timing shown in FIG. 3C, the baseband unit 4 executes the diversity control process for the bluetooth signal shown in FIG.
FIG. 4 is a flowchart for explaining the diversity control process for the bluetooth signal. This process is executed regardless of whether a PDC signal is waiting or a communication operation is in progress.
[0066]
As shown in FIG. 4, the baseband unit 4 first determines whether or not the bluetooth communication is being performed (step S1).
When the bluetooth communication operation is not in progress (step S1; No), only the normal PDC communication is performed, so the diversity operation for the bluetooth signal is not performed.
[0067]
If the bluetooth communication is being performed (step S1; Yes), the RSSI value measured by the bluetooth receiving circuit 21 is acquired, and it is determined whether or not the RSSI value is greater than a predetermined threshold (XdB) (step S1). S2).
[0068]
  When the RSSI value is larger than the predetermined threshold, that is, when the reception state is good (step S2; Yes), the detection output (I, Q signal) in the bluetooth reception circuit 21 without performing the diversity for the bluetooth signal. Is used as a bluetooth signal for subsequent processing in the baseband unit 4 (step S).5). During this time, since the diversity of the bluetooth signal is not executed, the power supply to the bluetooth receiving circuit 31 may be cut off.
[0069]
  If the RSSI value is less than or equal to a predetermined threshold, that is, if the reception status is not good (step S2; No), it is further determined whether or not a PDC signal is currently being received (step S2).3), When the PDC signal is received, that is, in the reception slot of the PDC reception circuit 11 (step S).3; Yes), the reception operation is performed only by the bluetooth reception circuit 21 without executing the diversity for the bluetooth signal (step S).5).
[0070]
  On the other hand, when the PDC signal is not received, that is, when the PDC communication standby operation is being performed, or when the PDC communication is being performed and is in the non-reception slot (step S).3; No), diversity for the bluetooth signal is executed (step S)4).
[0071]
That is, the baseband unit 4 switches the switch SW1 to the BPF 31a side, the detection output received from the bluetooth reception circuit 31 received by ANT1 or ANT2, and the detection output received from the bluetooth reception circuit 21 received by ANT3. Are used to select diversity after detection, or to combine received waves.
[0072]
The baseband unit 4 repeats the above steps S1 to S5. That is, when the PDC signal reception slot is reached, the switch SW1 is switched to the BPF 11a side, and the bluetooth signal diversity operation is stopped. When the PDC signal non-reception slot is reached, the switch SW1 is switched to the BPF 31a side and the bluetooth signal diversity operation is performed. Execute.
[0073]
As described above, the communication device 10 according to the present embodiment is a communication device in which both the PDC reception circuit 11 and the bluetooth reception circuit 21 are mounted. A part is shared and prepared. That is, the antennas ANT1 and ANT2 for PDC reception are shared as the antennas for bluetooth reception, and the LNA 11b of the PDC reception circuit 11 is shared. Also provided is a switch SW1 for switching the supply destination of the signals received by ANT1 and ANT2 to either the PDC reception circuit 11 side or the bluetooth reception circuit 31 side.
[0074]
Then, the baseband unit 4 is in the bluetooth communication, and when the PDC signal is not received in the PDC receiving circuit 11 (PDC standby and PDC non-receiving slot), the switch SW1 is switched to the bluetooth receiving circuit 31 side, The bluetooth receiving circuit 31 extracts the bluetooth signal from the received signal at the antenna ANT1 or ANT2, and the bluetooth receiving circuit 21 extracts the bluetooth signal from the received signal at the antenna ANT3. Diversity on the bluetooth signal is performed using the detection output from.
[0075]
Therefore, it is possible to provide two bluetooth receiving circuits while minimizing the circuit configuration, and to perform a diversity operation for the bluetooth signal. As a result, the communication quality of the bluetooth signal can be improved and a stable communication operation can be performed.
[0076]
In particular, since the antennas ANT1 and ANT2 for receiving the PDC signal are also used for receiving the bluetooth signal, it is not necessary to provide an antenna for each of the receiving circuits 11, 21, and 31, and the communication device 10 can be downsized.
[0077]
Further, since the LNA 11b of the PDC receiving circuit 11 is shared as a part of the bluetooth receiving circuit 31, the communication device 10 can be further downsized.
[0078]
In addition, the baseband unit 4 detects the reception status in the bluetooth reception circuit 21 and does not execute diversity for the bluetooth signal if the reception status is good. That is, only the bluetooth reception circuit 21 is operated, and the bluetooth reception circuit 31 is operated. Therefore, appropriate diversity control can be performed and power consumption can be reduced.
[0079]
In the above-described embodiment, an example in which a PDC reception circuit and a bluetooth reception circuit are mounted on the communication apparatus 10 has been described. However, the communication system is not limited to these, and for example, PDC Instead of the method, other communication methods such as GSM and IMT-2000 may be used.
[0080]
In this embodiment, one PDC receiving circuit is provided and two antennas are provided, and antenna switching diversity is performed for a PDC signal. However, the present invention is not limited to this. It is possible to further improve the diversity performance of the PDC signal by providing more than this, or to provide a plurality of PDC reception circuits 11 and perform post-detection selection diversity and received wave synthesis diversity for the PDC signal.
[0081]
In the above-described embodiment, the reception status is determined based on the RSSI value, but the present invention is not limited to this, and the reception status may be determined based on the bit error rate. In this case, if the bit error rate is smaller than a predetermined threshold, it is determined that the reception status is good.
[0082]
【The invention's effect】
According to the first aspect of the invention, apart from the second receiving circuit, a part of the first receiving circuit that receives the first wireless signal is shared to receive the second wireless signal. Since the receiving circuit is provided, two systems of receiving circuits for the second radio signal can be provided with a simple configuration. In addition, since the diversity control means executes the diversity for the second signal using the two receiving circuits (second and third) during the non-receiving operation in the first receiving circuit, The reception characteristic of the second radio signal can be improved while the circuit configuration of the entire apparatus is minimized, and a stable communication operation can be performed. Further, the switching control means automatically causes the third receiving circuit to receive the second radio signal during the receiving operation in the second receiving circuit and during the non-receiving operation in the first receiving circuit. Therefore, the diversity for the second radio signal can be executed in this section, and the reception characteristic of the second radio signal can be improved without disturbing the reception of the first radio signal. In addition, the reception status determination means determines the reception status in the second receiving circuit, and executes diversity for the second radio signal according to the determination result. If the reception status is good, the second radio Since it is not necessary to perform diversity on the signal, appropriate diversity control can be performed.
[0083]
According to the second aspect of the present invention, the diversity control means executes diversity for the first signal using the first receiving circuit during the receiving operation in the first receiving circuit. The reception characteristic of one radio signal can be improved, and a stable communication operation can be performed.
[0084]
According to the third aspect of the present invention, the first and third receiving circuits share the antenna, the first receiving circuit extracts the first radio signal from the received signal at the antenna, and the third receiving circuit Then, the second radio signal can be extracted, and the second receiving circuit can receive the second radio signal with an antenna different from the antenna. Therefore, the second radio signal is received from two different antennas. Diversity can be executed. Further, since a large-scale configuration such as an antenna can be shared by the first and third receiving circuits, the apparatus can be reduced in size.
[0085]
According to the invention of claim 4, since the first and third receiving circuits further share the power amplifier, the apparatus can be further downsized.
[0086]
According to invention of Claim 5, bluetooth Applying to mobile phones with built-in wireless communication functions according to the standard, while keeping the mobile phone terminal small, bluetooth Communication quality of wireless communication according to the standard can be improved.
[0087]
According to the sixth aspect of the invention, apart from the second receiving circuit, a part of the first receiving circuit that receives the first wireless signal is shared to receive the second wireless signal. In order to control the communication operation in the communication device including the receiving circuit, the third receiving circuit is in the receiving operation in the second receiving circuit and in the non-receiving operation in the first receiving circuit. The second radio signal is switched to be received, and the second and third receiving circuits are used to execute and control diversity for the second radio signal. In addition, since the reception situation in the second reception circuit is determined and it is determined whether or not to perform diversity for the second radio signal according to the determination result, the reception situation in the one reception circuit is good. Then, since it is not necessary to perform diversity for the second radio signal, appropriate diversity control can be performed.
[0088]
According to the seventh aspect of the present invention, the diversity control means executes diversity for the first signal using the first receiving circuit during the receiving operation in the first receiving circuit. The reception characteristic of one radio signal can be improved, and a stable communication operation can be performed.
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating an exemplary configuration of a communication device.
FIG. 2 is a diagram illustrating an example of transmission / reception timing in bluetooth communication.
FIG. 3 is a diagram illustrating a relationship between a transmission / reception timing of a PDC signal and a diversity operation timing for a bluetooth signal.
FIG. 4 is a flowchart for explaining diversity control processing for a bluetooth signal.
FIG. 5 is a block diagram showing a conventional configuration of a communication unit 100 of a PDC system mobile phone incorporating a communication circuit conforming to the bluetooth standard.
[Explanation of symbols]
10 Communication device
11 PDC receiver circuit (first receiver circuit)
12 PDC transmitter circuit
13 Antenna switch
ANT1 antenna
ANT2 antenna
21 bluetooth receiver circuit (second receiver circuit)
22 bluetooth transmitter circuit
23 Antenna selector
ANT3 antenna (second antenna)
31 bluetooth receiver circuit (third receiver circuit)
4 Baseband part
SW1 switch

Claims (7)

A first receiving circuit that receives a first radio signal corresponding to a first communication method that repeatedly performs a receiving operation and a non-receiving operation at predetermined time intervals ;
A second receiving circuit for receiving a second radio signal corresponding to a second communication method different from the first communication method;
A third receiving circuit different from the second receiving circuit for receiving the second radio signal by sharing at least a part of the first receiving circuit ;
Switching control means for switching to receive the second radio signal in the third receiving circuit during a receiving operation in the second receiving circuit and a non-receiving operation in the first receiving circuit; ,
Reception status determination means for determining the reception status in the second and third reception circuits;
Diversity control means for executing and controlling diversity for the second radio signal using the second and third receiving circuits;
With
The diversity control means controls execution of diversity for the second radio signal according to a determination result by the reception status determination means during a non-reception operation in the first reception circuit. apparatus.   The reception status determination means further determines a reception status in the first reception circuit,
The diversity control means executes diversity for the first radio signal using the first reception circuit according to a determination result by the reception status determination means during a reception operation in the first reception circuit. The communication apparatus according to claim 1, wherein the communication apparatus is controlled.   The first and third receiving circuits share at least an antenna;
  The first reception circuit includes a filter group that extracts the first radio signal from a reception signal at the antenna;
  The third receiving circuit includes a filter group that extracts the second radio signal from the received signal at the antenna;
  The communication apparatus according to claim 1, wherein the second reception circuit includes a filter group that extracts the second radio signal from a reception signal at a second antenna different from the antenna.   The communication apparatus according to claim 1, wherein the first and third receiving circuits further share a power amplifier.   The first communication method is a mobile phone communication method,
  The communication apparatus according to claim 1, wherein the second communication method is a wireless communication method in accordance with a Bluetooth standard.   A first receiving circuit that receives a first radio signal corresponding to a first communication method that repeatedly performs a receiving operation and a non-receiving operation at predetermined time intervals;
  A second receiving circuit for receiving a second radio signal corresponding to a second communication method different from the first communication method;
  A third receiving circuit different from the second receiving circuit for receiving the second radio signal by sharing at least a part of the first receiving circuit;
  A communication control method in a communication device comprising:
  A switching control step of switching to receive the second radio signal in the third receiving circuit during a receiving operation in the second receiving circuit and a non-receiving operation in the first receiving circuit; ,
  A reception status determination step of determining a reception status in the second and third reception circuits;
  A diversity control step of executing and controlling diversity for the second radio signal using the second and third receiving circuits;
  Including
  The diversity control step controls execution of diversity for the second radio signal according to a determination result of the reception state determination step during a non-reception operation in the first reception circuit. Control method.   The reception status determination step further determines a reception status in the first reception circuit,
The diversity control step executes diversity for the first radio signal using the first reception circuit according to a determination result in the reception state determination step during a reception operation in the first reception circuit. The communication control method according to claim 6, wherein control is performed.

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