JP3811928B2 - Wireless communication system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a wireless communication system including a parent device and at least one child device, and in particular, sets the best transmission power level when communicating between the parent device and the child device for each communication between the parent device and the child device. Related to what I did.
[0002]
[Prior art]
Conventionally, in a building, a base unit connected to an external line and a telephone cordless handset that is a plurality of cordless telephones are installed, and wireless communication is performed using digital signals between the base phone and each telephone cordless handset. Cordless telephone systems that enable (wireless calls) are in practical use. Recently, in this cordless telephone system, transmission of the master unit and the telephone slave unit can be performed so that the communication distance when performing parent-child communication between the master unit and the telephone slave unit can be increased, for example, as 100 to 150 meters. The unit is provided with a high-frequency amplifier capable of obtaining a transmission power as large as 100 mw, for example, while the transmission power can be changed according to the communication distance.
[0003]
That is, when the telephone slave unit is installed at a position close to the master unit, the transmission power of the master unit and the telephone slave unit that communicate with each other is set to a substantially maximum value. When the received voice data is received by the telephone handset, if the received signal is distorted because the electric field strength of the transmission wave transmitted from the base handset received by the telephone handset is too strong, the receiving side As a result of demodulating the distorted reception signal, the distorted audio signal is reproduced, so that the transmitted voice cannot be heard clearly on the telephone handset side. Therefore, at the start of communication, the transmission power setting for setting the transmission power satisfactorily is performed in each of the parent device and the telephone child device communicating with each other.
[0004]
When setting the transmission power, even when the base unit and the telephone handset are installed at a long distance from the base unit, the communication partner can be called reliably so that they can call each other. The transmission power of each of the master unit and the telephone slave unit is set to approximately maximum, and the test data is transmitted to the other party with the maximum transmission power. Then, the data of the error occurrence rate at the time of receiving the test data is received from the other side, and when the error occurrence rate is high, the transmission power is reduced and the test data is transmitted again, and finally By setting the optimal transmission power that enables a call without distortion in the audio signal, it is always good and clear between the parent and child regardless of the communication distance between the parent device and the phone child device. Wireless communication is now possible.
[0005]
[Problems to be solved by the invention]
As described above, in a cordless telephone system that enables wireless communication between a parent device and a plurality of telephone child devices, each time parent-child communication is performed, transmission power is gradually increased from approximately maximum at the time of parent-child communication. The test data is repeatedly transmitted while reducing to a low level, and finally the transmission power setting is performed to set the transmission power that does not cause distortion in the audio signal. There is a problem that it takes time until a call can be made after calling the other party for wireless communication. An object of the present invention is to provide a wireless communication system capable of performing communication between a parent device and a child device quickly and optimally with no distortion after calling the other party.
[0006]
[Means for Solving the Problems]
The wireless communication system according to claim 1 is connected to an external communication line and transmits and receives voice data and non-voice data via the external communication line, and voice data and non-wirelessly by wireless communication between the parent machine. In a wireless communication system including at least one slave unit that transmits and receives audio data, the master unit includes a line control unit that performs line control on an external communication line, a transmission and reception unit that performs transmission and reception between the slave units, Frequency data storage unit for storing frequency data of frequency of use for each of a plurality of transmission power levels used for past multiple times of wireless communication with the child device, and frequency data storage for wireless communication with the child device The most frequently used transmit power level based on Select Power level setting means for setting.
[0007]
In the master unit, line control for the external communication line is performed by the line control unit. In addition, when performing transmission / reception with the slave unit by the transmission / reception unit, the frequency data storage unit stores the usage frequency for each of a plurality of transmission power levels used in the past many times of wireless communication for each slave unit. Since the frequency data is accumulated, the power level setting means determines the most frequently used transmission power level based on the data in the frequency data storage unit. Select Therefore, the transmission / reception unit performs transmission / reception with the slave unit at the transmission power level. Then, the frequency of use of the transmission power level used for the communication is added and stored in the frequency data storage unit.
[0008]
That is, when a wireless communication system comprising a master unit and a slave unit is provided inside a building, generally, each of the plurality of slave units is generally fixedly installed at a point convenient for talking with the master unit. On the other hand, since the master unit is fixedly installed at a position where it can communicate with each slave unit, the communication distance between the master unit and the slave unit is substantially constant. In addition, by using the most frequently used transmission power level, it is possible to set the best transmission power level for the slave unit on the base unit side early and to start communication at an early stage.
[0009]
According to a second aspect of the present invention, there is provided a wireless communication system according to the first aspect of the present invention, wherein the slave unit includes a transmission / reception unit that performs transmission / reception with the master unit, and a plurality of transmissions used for many past wireless communications with the master unit. A frequency data storage unit that accumulates frequency data of frequency of use for each power level, and the most frequently used transmission power level based on the data in the frequency data storage unit during wireless communication with the master unit Select Power level setting means for setting.
In this case, since the slave unit is also provided with a transmission / reception unit, a frequency data storage unit, and a power level setting unit as in the case of the master unit, when the transmission / reception unit performs transmission / reception with the master unit, By using the most frequently used transmission power level when transmitting from the device to the parent device, the best transmission power level for the parent device on the child device side can be set early, and communication can be started early. In addition, the same effects as those of the first aspect are achieved.
[0010]
According to a third aspect of the present invention, there is provided the wireless communication system according to the first aspect, wherein the power level setting means of the master unit receives a test data from a slave unit and a test data storage unit for storing test data of a predetermined pattern set in advance. Means for receiving error data indicating the error occurrence rate at the time and determining whether the transmission power level is good or not, and the most frequently used transmission power level at the start of transmission to the transmission / reception unit based on the data in the frequency data storage unit Power level selection control means for transmitting and outputting test data and transmitting and outputting test data at a transmission power level that is used less frequently until the transmission power level becomes good.
[0011]
In this case, since the test data storage unit stores test data of a predetermined pattern in the power level setting unit, the power level selection control unit transmits the most frequently used transmission power level at the start of transmission to the transmission / reception unit. Since the test data is transmitted and output at, the error data indicating the error occurrence rate at the time of receiving the test data is received from the slave unit by the transmission / reception unit, so the determination means determines whether the transmission power level is good or bad based on the error data. Determined. When the determination means determines that the transmission power level is negative, the power level selection control means sequentially transmits test data at a transmission power level that is used less frequently until it is determined to be good. Finally, the best transmission power level is set for communication with the slave unit. In addition, the same effects as those of the first aspect are achieved.
[0012]
According to a fourth aspect of the present invention, there is provided the wireless communication system according to the second aspect, wherein the power level setting means of the slave unit receives a test data from the master unit, and a test data storage unit that stores test data of a predetermined pattern set in advance. Means for receiving error data indicating the error occurrence rate at the time and determining whether the transmission power level is good or not, and the most frequently used transmission power level at the start of transmission to the transmission / reception unit based on the data in the frequency data storage unit Power level selection control means for transmitting and outputting test data and transmitting and outputting test data at a transmission power level that is used less frequently until the transmission power level becomes good.
[0013]
In this case, the power level setting means of the slave unit is also provided with a test data storage unit, a determination unit, and a power level selection control unit as in the case of the master unit. Until the transmission power level is determined to be good, the test data is transmitted and output at the least frequently used transmission power level, and finally the best transmission power level is set for communication with the master unit. The In addition, the same effects as those of the second aspect are achieved.
[0014]
According to a fifth aspect of the present invention, in the wireless communication system according to the fourth aspect, when the slave unit receives test data from the master unit, the slave unit calculates an error occurrence rate and sends error data indicating the error occurrence rate to the master unit. In contrast, test response means for instructing the transmission / reception unit to transmit and output is provided. In this case, when the test response means provided in the slave unit receives the test data from the master unit, it calculates the error occurrence rate, and transmits error data indicating the error occurrence rate to the master unit. Thus, the master unit can receive the error data from the slave unit reliably and promptly. In addition, the same effects as in the fourth aspect are obtained.
[0015]
According to a sixth aspect of the present invention, in the wireless communication system according to the third aspect, when the master unit receives test data from the slave unit, the master unit calculates an error occurrence rate and sends error data indicating the error occurrence rate to the slave unit. In contrast, test response means for instructing the transmission / reception unit to transmit and output is provided. In this case, the master unit is provided with the test response means in the same manner as the slave unit, so that the slave unit can reliably and quickly receive error data from the master unit. In addition, the same effects as in the third aspect are achieved.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the present embodiment, the present invention is applied to a wireless communication system provided inside a building. As shown in FIG. 1, the wireless communication system 1 includes a facsimile apparatus 4 as a master unit connected to a general commercial analog telephone line 2 or a digital transmission network 3, and three telephone slave units 6 including cordless telephones. ~ 8. Here, with respect to the facsimile apparatus 4, the telephone handset 6 is installed at a position at a close distance, the telephone handset 7 is installed at a position farther than the telephone handset 6, and the telephone handset 8 is installed at a telephone handset. It is installed at a position farther than the machine 7.
[0017]
First, the facsimile machine 4 will be described. As shown in FIG. 2, the facsimile apparatus 4 is connected to an external communication line such as a general commercial analog telephone line 2 or a digital transmission network 3 and has a parent / child telephone function in addition to a scanner function, a facsimile function, and a printing function. A transmission / reception unit 41 having an antenna 42, a line control unit 43 for controlling connection between the external communication lines 2 and 3, a conversion unit 44 for mutual conversion between an analog signal and a digital signal, and the conversion unit 44, a handset (receiver) 45 connected to 44, a data processing unit 46, a control unit 47 including a microcomputer, and the like.
[0018]
Further, the control unit 47 includes a recording unit 48 provided with a laser printer, a reading unit 49 provided with a scanner for reading an image of a document, a frequency data storage unit 50, and ID codes (telephones 6 to 8). An ID code storage unit 51 that stores a recognition code), a test data storage unit 52, a display unit 53, an operation unit 54, and the like are connected. The transmission / reception unit 41 includes a modulator, a demodulator, a frequency converter, an amplifier, a transmission / reception changeover switch, a PLL (Phase locked loop) local oscillator, etc. (not shown).
[0019]
That is, in the modulator, the carrier wave is frequency-modulated by digital audio data or non-audio data by, for example, FSK (Frequency Shift Keying) method, and an intermediate frequency signal is output. This intermediate frequency is converted into a high-frequency signal having a predetermined frequency based on the local oscillation frequency supplied from the PLL local oscillator in the frequency converter. At this time, the local oscillation frequency oscillated by the PLL local oscillator is controlled by the control unit 47. The high frequency signal converted by the frequency converter is amplified by an amplifier and then transmitted to the antenna 42 via the transmission / reception changeover switch.
[0020]
Here, the amplification factor by the amplifier, that is, the magnitude of the transmission power is controlled based on the transmission power level commanded from the control unit 47. On the other hand, the high frequency signal received by the antenna 42 is amplified by an amplifier via a transmission / reception selector switch, and then the frequency converter converts the high frequency signal to an intermediate frequency signal based on the local oscillation frequency output from the PLL local oscillator. And demodulated by a demodulator. The data processing unit 46 performs various types of data processing, such as compression processing at the time of transmission and decompression processing at the time of reception of audio data and non-voice data.
[0021]
The conversion unit 44 includes a D / A converter and an A / D converter, converts an analog signal supplied from the line control unit 43 into a digital signal, and outputs the digital signal to the transmission / reception unit 41 and the handset 45. The digital signal supplied from the unit 41 or the handset 45 is converted into an analog signal and output to the line control unit 43. In the frequency data storage unit 50, as shown in FIG. 4A, three levels of transmission power levels, that is, transmission outputs, used for many past wireless communications are stored for each of the telephone slave units 6-8. A usage frequency table for storing and storing frequency data of usage frequency for each of “H” having a large transmission output, “M” having a medium transmission output, and “L” having a small transmission output is stored.
[0022]
The ID code storage unit 51 stores ID codes (recognition codes) of the telephone slave units 6 to 8 that have started communication. The test data storage unit 52 stores test data having a predetermined pattern of, for example, 125 bits, which is a combination of a plurality of “1” and “0” so that the quality of the communication state can be detected. Next, although the telephone subunit | mobile_units 6-8 are demonstrated, since these telephone subunit | mobile_units 6-8 are comprised similarly, the telephone subunit | mobile_unit 6 is demonstrated based on FIG.
[0023]
The telephone slave 6 includes a transmission / reception unit 61 having an antenna 62, a conversion unit 63 that performs mutual conversion between an analog signal and a digital signal, a microphone 64 and a speaker 65 connected to the conversion unit 63, and a data processing unit 66. And a control unit 67 composed of a microcomputer. Further, the control unit 67 includes a frequency data storage unit 68, an ID code storage unit 69 for storing a dedicated ID code in the telephone cordless handset 6, a test data storage unit 70, a display unit 71, and an operation unit. 72 etc. are connected. Here, the operations in the units 61 to 72 are the same as those of the units 41 to 42, 44, 46 to 47, and 50 to 54 provided in the facsimile machine 4, and thus the description thereof is omitted.
[0024]
Here, in the frequency data storage unit 68, as shown in FIG. 5A, as the transmission power level when communicating with the facsimile apparatus 4, the three stages used in the past many times of wireless communication are used. There is a usage frequency table for accumulating and storing frequency data of usage frequency for each of the transmission power level, that is, “H” with a large transmission output, “M” with a medium transmission output, and “L” with a small transmission output. Stored.
[0025]
Since the facsimile apparatus 4 and the telephone slave units 6 to 8 are configured as described above, for example, when wireless communication is performed between the facsimile apparatus 4 and the telephone subunit 6, the facsimile apparatus 4 includes a handset. The audio signal generated from the 45 microphones 45a and the test data in the test data storage unit 52 are compressed by the data processing unit 46, then frequency-modulated by the transmission / reception unit 41, and transmitted at the set transmission power level. Then, it is transmitted as a transmission wave from the antenna 42.
[0026]
On the other hand, test data and audio data received by the antenna 42 are demodulated by the transmission / reception unit 41 and decompressed by the data processing unit 46. For the test data, the error occurrence rate is calculated by the control unit 47, and the result of the calculation is obtained. Error data is wirelessly transmitted to the telephone handset 6 via the transmission / reception unit 41. The audio data is converted into an analog audio signal by the converter 44, and the audio is output from the speaker 45b. In the telephone handset 6, the voice signal generated from the microphone 64 and the test data in the test data storage unit 70 are compressed by the data processing unit 66 and then frequency-modulated by the transmission / reception unit 61, as in the facsimile device 4. The antenna 62 transmits the transmission wave as a transmission wave with the transmission power of the set transmission power level.
[0027]
On the other hand, test data and audio data received by the antenna 62 are demodulated by the transmission / reception unit 61 and decompressed by the data processing unit 66. For the test data, the error occurrence rate is calculated by the control unit 67, and the result of the calculation is calculated. Error data is wirelessly transmitted to the facsimile machine 4 via the transmission / reception unit 61. The audio data is converted into an analog audio signal by the conversion unit 63, and audio is output from the speaker 65.
[0028]
Next, regarding the communication control routine of the facsimile apparatus executed by the control unit 47 of the facsimile apparatus 4, the telephone executed by the control unit 67 of the telephone slave units 6-8 based on the flowcharts of FIGS. A slave communication control routine will be described with reference to the flowcharts of FIGS. However, it is assumed that communication is performed between the facsimile apparatus 4 and the telephone handset 6. Further, in the frequency data storage unit 50 of the facsimile apparatus 4, as shown in FIG. 4A, three levels of transmission power levels “H”, “M”, and “L” for each of the telephone slave units 6 to 8 are stored. For each usage frequency, default frequency data is stored as shown. Symbol Si (i = 10, 11, 12,...) In the figure is each step.
[0029]
Further, in the frequency data storage unit 68 of the telephone cordless handset 6, as shown in FIG. 5A, three levels of transmission power levels “H”, “M”, As shown in the figure, default frequency data is stored for the usage frequency for each of “L”. In the communication control of the telephone handset shown in FIG. 8, when calling the facsimile apparatus 4 by transmitting a calling signal including the ID code of the telephone handset 6 (S50: Yes), the facsimile apparatus 4 is called (S57). Next, based on the data in the usage frequency table, the most frequently used transmission power level PBH is read (S53), and the control unit 67 sends the transmission power level PBH as the transmission power level to the amplifier of the transmission / reception unit 61. (S54).
[0030]
That is, when the most frequently used transmission power level PBH is “H”, the transmission / reception unit 41 transmits and outputs at the maximum power. Next, the telephone handset side transmission power level setting process control (see FIG. 9) is executed (S55). When this control is started, reception of a signal transmitted from the facsimile machine 4 is first waited (S60: No). By the way, since the facsimile apparatus 4 is called from the telephone handset 6 (S10: No, S11: Yes), the call signal is analyzed and the telephone handset 6 called based on the ID code included in the call signal. Is recognized (S12), and based on the usage frequency table of FIG. 4A, the most frequently used transmission power level PAH for the telephone cordless handset 6 is read (S13). The amplifier is commanded to have a transmission power level PAH as a transmission power level (S14).
[0031]
Next, the test data is read from the test data storage unit 52 and transmitted to the telephone handset 6 (S15), and setting processing for setting the transmission power level on the facsimile machine 4 side, that is, the base unit side (see FIG. 7). ) Is executed (S16). When this control is started, reception of a signal transmitted from the telephone handset 6 is first waited (S30: No). By the way, in the telephone cordless handset 6, when the test data is transmitted from the facsimile apparatus 4 (S60: Yes), when the transmission power level setting on the facsimile apparatus 4 side is not fixed (S61: No), the reception is received. By comparing the test data with the test data in the test data storage unit 70, an error occurrence rate at the time of receiving the test data is calculated (S62).
[0032]
Next, when the transmission power level setting on the telephone handset 6 side is not fixed (S63: No), when no error data is received (S64: No), the test data is read from the test data storage unit 70. When the transmission power level setting on the facsimile apparatus 4 side is not fixed (S69: No), error data indicating the error occurrence rate calculated in S62 is further transmitted to the facsimile apparatus 4 (S68). 4 is transmitted and output (S70). On the other hand, in the facsimile apparatus 4, when the test data and error data transmitted from the telephone handset 6 are received (S30: Yes), when the transmission power level setting on the telephone handset 6 side is not finalized ( (S31: No), by comparing the received test data with the test data in the test data storage unit 52, the error occurrence rate at the time of receiving the test data is calculated (S32).
[0033]
Next, when the transmission power level setting on the facsimile apparatus 4 side is not finalized (S33: No), when the error value EN of the received error data is larger than a predetermined value J that can tolerate the error, that is, in the received signal. If large distortion has occurred (S34: No), the next least frequently used transmission power level PAN is read (S35), and the transmission power level is transmitted to the transmission / reception unit 41 as the transmission power level. It is commanded to become PAN (S36). Then, in order to set the transmission power level again, test data is transmitted (S37), and when the transmission power level setting on the telephone handset 6 side is not finalized (S38: No), an error calculated in S32 occurs. Error data indicating the rate is transmitted to the telephone handset 6 (S39).
[0034]
Next, in the telephone handset 6, when the test data and error data transmitted from the facsimile apparatus 4 are received (S60: Yes), when the transmission power level setting on the facsimile apparatus 4 side is not confirmed (S60: Yes) S61: No), the error occurrence rate at the time of test data reception is calculated (S62), and the transmission power level setting on the telephone handset 6 side is not finalized (S63: No), and error data is received Sometimes (S64: Yes), when the error value EN of the received error data is larger than the predetermined value J, that is, when a large distortion occurs in the received signal (S65: No), the next least frequently used The transmission power level PBN is read (S66), and the transmission / reception unit 61 is instructed to become the transmission power level PBN as the transmission power level (S67). Then, S68 to S70 are executed in order to set the transmission power level again.
[0035]
Similarly, the test data is transmitted and output on both the facsimile apparatus 4 side and the telephone handset 6 side. On the other hand, if the error value EN of the received error data is large, the transmission power level becomes good. In turn, the transmission power level is changed to the next least frequently used transmission power level. That is, in the facsimile apparatus 4, based on the usage frequency table of FIG. 4A, the “H” transmission power level with the highest usage frequency is used at the start of communication, but the “M” transmission power level → “ The “L” transmission power level is sequentially changed. Similarly, the telephone handset 6 uses the “H” transmission power level with the highest usage frequency at the start of communication, but the “M” transmission power level. → The transmission power level is sequentially changed to “L”, and test data is transmitted and output at the changed transmission power level.
[0036]
By the way, in the facsimile apparatus 4, when the error value EN of the received error data is not more than the predetermined value J, that is, the distortion of the received signal is small and the received voice can be heard almost clearly (S34: Yes), A confirmation signal confirming the setting of the transmission power level is transmitted to the telephone handset 6 (S40). In this case, only error data is transmitted and output to the telephone handset 6 without transmitting test data (S38: No, S39). At this time, only the error data is received at the telephone handset 6 (S60: Yes), and the facsimile apparatus 4 side has been confirmed (S61: Yes), so S62 is skipped and S63 to S68 are executed, and an error occurs. Data is not transmitted (S69: Yes). As a result, in the facsimile apparatus 4, only the error data of the received test data is transmitted and output to the telephone handset 6 (S30: Yes, S31: No, S32, S33: Yes, S41: No, S38: No, S39)
[0037]
On the other hand, if the error value EN of the received error data is equal to or less than the predetermined value J, that is, the distortion of the received signal is small and the received voice can be heard almost clearly (S65: Yes). Then, a confirmation signal confirming the setting of the transmission power level is transmitted to the facsimile apparatus 4 (S71). In this case, test data and error data are not transmitted to the facsimile machine 4 (S69: Yes).
[0038]
In the facsimile apparatus 4, only the confirmation signal is received (S30: Yes), and both the facsimile apparatus 4 side and the telephone slave unit 6 are confirmed (S31: Yes, S33: Yes, S41: Yes), so the frequency For the usage frequency table of the data storage unit 50, a change process is performed in which the usage frequency of the transmission power level used for the current wireless communication is added and stored in the usage frequency table (S42), and the communication start signal is the telephone slave unit 6 (S43), the control is terminated, and the process returns to S17 of the facsimile apparatus communication control. Then, in the communication control of the facsimile apparatus, a communication process is executed with the telephone handset 6 with the transmission power of the optimum transmission power level finally set (S17).
[0039]
That is, as shown in FIG. 4B, since the telephone handset 6 is installed at a position close to the facsimile apparatus 4, a number of past wireless communication with the telephone handset 6 has been executed. As a result, the largest number of times of use of the transmission power level “L” for reducing the transmission power is accumulated. Further, in the telephone handset 6, only the communication start signal is received (S60: Yes), and both the telephone handset 6 and the facsimile apparatus 4 are confirmed (S61: Yes, S63: Yes, S72: Yes). In the usage frequency table of the frequency data storage unit 68, a change process for adding the usage frequency of the transmission power level used for the current wireless communication and storing it in the usage frequency table is executed (S73). Then, the process returns to S56 in the communication control of the telephone handset.
[0040]
Then, in the communication control of the telephone handset, communication processing is executed with the facsimile apparatus 4 at the optimum transmission power level finally set (S56). That is, as shown in FIG. 5B, as a result of performing a number of past wireless communications with the facsimile apparatus 4, the number of times of use of the transmission power level “L” that decreases the transmission power is accumulated most. As described above, in the usage frequency table of FIG. 4B, the telephone handset 7 is located at an intermediate distance with respect to the facsimile apparatus 4, and therefore, the transmission power level “M” that makes the transmission power medium. Is stored most frequently, and the telephone handset 8 is located at a long distance from the facsimile apparatus 4, and therefore, the most frequently used transmission power level “H” that maximizes transmission power is stored. Is done.
[0041]
On the other hand, in the communication control of the facsimile apparatus of FIG. 6, when calling the telephone handset 6 by transmitting a call signal including the ID code of the telephone handset 6 (S10: Yes), the telephone handset 6 of the communication destination is called. (S18) The transmission power level PAH with the highest usage frequency of the telephone handset 6 is read from the usage frequency table (S19). Then, S14 and subsequent steps are executed. In the communication control of the telephone handset shown in FIG. 8, when the facsimile apparatus 4 is called by a calling signal including the ID code of the facsimile apparatus 4 (S50: No, S51: Yes), the received calling signal is analyzed. (S52), S53 and subsequent steps are executed.
[0042]
Here, in the facsimile apparatus 4, the base unit side transmission power level setting process control corresponds to the power level setting means, S34 corresponds to the determination means, and the power level selection control means includes S35 to S37. The test response means is constituted by S39 and the like. Further, in the telephone slave units 6 to 8, the telephone slave unit side transmission power level setting process control corresponds to the power level setting means, S65 corresponds to the determination means, and the power level selection control means includes S66 to S68. , S62, S70, etc. constitute test response means.
[0043]
As described above, in the wireless communication system 1 including the facsimile apparatus 4 and the telephone slave units 6 to 8, the facsimile apparatus 4 includes the line control unit 43, the transmission / reception unit 41, the power level storage unit 50, and the like. 4 to the telephone slave units 6 to 8, by using the most frequently used transmission power level PAH based on the data of the usage frequency table stored in the frequency data storage unit 50, the facsimile apparatus 4 side The best transmission power level for the telephone slave units 6 to 8 can be set at an early stage, and a call can be made quickly and optimally without distortion by calling the other party.
[0044]
Similarly, the telephone slave units 6 to 8 are provided with a transmission / reception unit 61, a frequency data storage unit 68, etc., and stored in the frequency data storage unit 68 when transmitting from the telephone slave units 6 to 8 to the facsimile apparatus 4. By using the most frequently used transmission power level PBH based on the data of the usage frequency table, the best transmission power level for the facsimile apparatus 4 on the side of the telephone slave units 6 to 8 can be set at an early stage, and the other party is called. After that, it is possible to make a call quickly and with optimum transmission power without distortion.
[0045]
In addition, the facsimile apparatus 4 and the telephone slave units 6 to 8 are provided with test data storage units 52 and 70 to transmit the test data, while the transmission power level is good based on the received error data indicating the error occurrence rate. Until it is determined that the transmission power level is less frequently used, the best transmission power level at the moving position can be easily set even when the telephone handsets 6 to 8 move. .
[0046]
Here, as a modified form of the embodiment, a wireless communication system including a facsimile apparatus 4 as a base unit, a plurality of telephone slave units, and a non-voice terminal unit including a wireless modem connected with a personal computer is provided. Even when the facsimile apparatus 4 and these non-voice terminals are communicated by non-voice data, the transmission power level with the highest use frequency may be set. Alternatively, error detection data may be added to the test data and transmitted, and the error occurrence rate may be calculated based on the error detection data on the receiving side. Furthermore, the present invention should not be construed as being limited to the above-described embodiments, and within the scope not departing from the technical idea of the present invention, existing controls or controls obvious to those skilled in the art can be used for the control of each part of the above-described embodiments. Various modifications may be made based on the above.
[0047]
【The invention's effect】
According to the wireless communication system of claim 1, voice data is transmitted by wireless communication between the master unit connected to the external communication line and transmitting / receiving voice data and non-voice data via the external communication line. In the wireless communication system including at least one slave unit that transmits and receives non-voice data, the master unit includes a line control unit, a transmission / reception unit, a frequency data storage unit, and a power level setting unit. By using the most frequently used transmission power level when transmitting from the machine to the child machine, the best transmission power level for the child machine on the parent machine side can be set early, and communication can be started early. it can.
[0048]
According to the wireless communication system of the second aspect, the same effect as in the first aspect is obtained, but the slave unit includes a transmission / reception unit, a frequency data storage unit, and a power level setting unit, similar to the master unit. Therefore, when transmitting from the slave unit to the master unit, the best transmission power level for the master unit on the slave unit side can be set early by using the most frequently used transmission power level, and communication is started early. can do. According to the wireless communication system of claim 3, the same effect as that of claim 1 is obtained, but the power level setting means of the master unit includes a test data storage unit, a determination means, and a power level selection control means. Therefore, until the transmission power level is determined to be good, test data is transmitted and output at the transmission power level that is used infrequently, and finally the best transmission power level is set for communication with the slave unit. Is done.
[0049]
According to the wireless communication system of claim 4, the same effect as that of claim 2 is obtained, but the power level setting means of the slave unit is similar to the power level setting means of the master unit, and the test data storage unit And the power level selection control means, the test data is transmitted and output at the transmission power level that is used in order, until the transmission power level is determined to be good, as in the third aspect. Finally, the best transmission power level is set for communication with the parent device.
[0050]
According to the wireless communication system of the fifth aspect, the same effect as in the fourth aspect is achieved, but the slave unit calculates an error occurrence rate when the test data is received from the master unit, and indicates the error occurrence rate. Since the test response means for instructing the transmission / reception unit to transmit and output error data to the parent device is provided, the parent device can reliably and promptly receive error data from the child device. According to the radio communication system of claim 6, the same effect as that of claim 3 is obtained, but since the master unit is provided with test response means in the same manner as the slave unit, the slave unit has an error from the master unit. Data can be received reliably and quickly.
[Brief description of the drawings]
FIG. 1 is a configuration diagram of a radio communication system according to an embodiment of the present invention.
FIG. 2 is a schematic configuration diagram of a facsimile apparatus.
FIG. 3 is a schematic configuration diagram of a telephone handset.
FIG. 4 is a chart showing a data structure of a usage frequency table of a facsimile machine, where (a) is a usage frequency for each transmission power level set at the start of communication with each telephone handset, and (b) is a past record. This is the frequency of use for each transmission power level set by multiple times of wireless communication.
FIG. 5 is a chart showing a data structure of a usage frequency table of a telephone handset, where (a) is a usage frequency for each transmission power level set at the start of communication, and (b) is a radio frequency of past times. This is the usage frequency for each transmission power level set by communication.
FIG. 6 is a flowchart of a communication control routine of the facsimile apparatus.
FIG. 7: Base unit side transmission power level setting process control of It is a flowchart of a routine.
FIG. 8 is a flowchart of a communication control routine of the telephone handset.
[Fig. 9] Telephone slave unit side transmission power level setting process control of It is a flowchart of a routine.
[Explanation of symbols]
1 Wireless communication system
2 telephone lines
3 Digital transmission network
4 facsimile machines
6-8 telephone cordless handset
41 Transceiver
43 Line control unit
47 Control unit
50 Frequency data storage
52 Test data storage
61 Transceiver
68 Frequency data storage
70 Test data storage

Claims (6)

A master unit connected to an external communication line and transmitting / receiving voice data and non-voice data via the external communication line, and at least one child transmitting / receiving voice data and non-voice data by wireless communication between the parent unit In a wireless communication system equipped with a machine,
The master unit is a line control unit that performs line control for an external communication line;
A transmission / reception unit for transmitting / receiving data to / from the slave unit;
A frequency data storage unit that accumulates frequency data of usage frequency for each of a plurality of transmission power levels used in the past many times of wireless communication for each slave unit;
A wireless communication system comprising power level setting means for selecting and setting a transmission power level having the highest use frequency based on data in a frequency data storage unit during wireless communication with a slave unit. The slave unit accumulates frequency data of the frequency of use for each of a plurality of transmission power levels used for a plurality of past wireless communications with the master unit, and a transmission / reception unit that performs transmission / reception with the master unit A frequency data storage unit, and power level setting means for selecting and setting the most frequently used transmission power level based on data in the frequency data storage unit during wireless communication between the master unit and the frequency data storage unit The wireless communication system according to claim 1.   The power level setting means of the master unit receives a test data storage unit that stores test data of a predetermined pattern set in advance, and error data indicating an error occurrence rate at the time of test data reception from the slave unit, and a transmission power level Based on the data in the frequency data storage unit, the transmission / reception unit transmits and outputs test data at the most frequently used transmission power level and the transmission power level becomes good based on the data in the frequency data storage unit The wireless communication system according to claim 1, further comprising power level selection control means for transmitting and outputting test data at a transmission power level having a low usage frequency in order.   The power level setting means of the slave unit includes a test data storage unit that stores test data of a predetermined pattern set in advance, and error data indicating an error occurrence rate at the time of receiving test data from the master unit, and a transmission power level Based on the data in the frequency data storage unit, the transmission / reception unit transmits and outputs test data at the most frequently used transmission power level and the transmission power level becomes good based on the data in the frequency data storage unit The wireless communication system according to claim 2, further comprising power level selection control means for transmitting and outputting test data at a transmission power level having a low usage frequency in order.   When the slave unit receives test data from the master unit, the slave unit calculates a test error rate, and sends test response means to instruct the transmitter / receiver to transmit error data indicating the error rate to the master unit. The wireless communication system according to claim 4, further comprising:   When the master unit receives test data from the slave unit, the master unit computes an error occurrence rate, and sends test response means for instructing the transmission / reception unit to transmit error data indicating the error occurrence rate to the slave unit. The wireless communication system according to claim 3, further comprising:

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