SK286817B6 - Process for operating a telecommunication terminal, telecommunication terminal and radio module - Google Patents

Abstract

A process for operating a telecommunication terminal, a telecommunication terminal and a radio module make it possible to use a telecommunication terminal in a more simple and versatile manner. When a connection is requested, the telecommunication terminal (1) checks whether a wireless connection can be established with the radio module (5). When a wireless connection with the radio module (5) can be established, signals are wirelessly transmitted from the telecommunication terminal (1) to the radio module (5). The radio module (5) transmits signals with a predetermined power derived from the signals received from the telecommunication terminal (1). In interrupting of a wireless transmission between the telecommunication terminal (1) and the radio module (5), the signals are radiated with a further second predetermined power into the radio network by the telecommunication terminal (1), the second predetermined power being greater than the first transmit power. Telecommunication terminal (1), preferably radio device, has interface (10) for a wireless data exchange with a radio module (5), with a transmitting unit (25), with a radio unit (30), which is connected to transmitting/receiving antenna (50), with the test device (15) for driving switch (20), connected with switch (20) in such a manner that it connects the transmitting unit (25) to a radio unit (30) for radiating signals with predetermined power.

Description

Technical field

The present invention relates to a method of operating a telecommunications broadcasting device in which, when a connection request is made by a telecommunications broadcasting device, it is examined whether a wireless connection to the radio module can be established, and in case the wireless connection to the radio module can be established between the telecommunications broadcasting device. The device and radio module wirelessly transmit the first transmit power signals, and the radio module transmits predetermined power signals to the radio network, which are derived from the received telecommunication transmit device signals. The invention further relates to a telecommunications transmission device, in particular a radio device with a wireless data interchange interface.

BACKGROUND OF THE INVENTION

It is already known from the German patent application 197 05 447 that radio equipment can be operated at different power levels so that it can be used flexibly. A low-power low-cost radio device can be easily equipped to operate at a higher power level by means of a connectable high-frequency amplifier circuit. The range of the radio device of the first predetermined power stage can be increased by simple means by connecting a high-frequency amplifier circuit.

DE 35 28 886 discloses a radiotelephone system with mobile stations, base stations and portable terminals. There is provided a first mode of operation in which a radio connection is used between the base station and the portable terminal. This type of operation is a preferred type of operation that requires higher transmission power of the portable terminal. If this first mode of operation cannot be maintained, for example due to a lack of connection between the handheld terminal and the base station, the second mode of operation is established to establish a connection between the mobile station and the handheld terminal.

WO 92/10046 discloses a cellular telephone system, whereby an infrared connection is first established between the handset and the relay station for radio communication between the handset and the base station. The relay station is equipped with an antenna which guarantees radio connection to the base station.

SUMMARY OF THE INVENTION

This improves the method of operation of a telecommunications broadcasting device, in which, when a connection request is made by a telecommunications broadcasting device, it is checked whether a wireless connection to the radio module can be established, and in case the wireless connection to the radio module can be established between the telecommunications broadcasting device. the device and radio module wirelessly transmit the first transmit power signals and from the radio module transmit predetermined power signals to the radio network, which are derived from the received signals of the telecommunication transmitter according to the invention, which is based on the interruption of wireless transmission between the telecommunication transmitter With the device and radio module, signals of another, second predetermined power, and the second predetermined power, are transmitted from the telecommunication transmitter to the radio network. the power is greater than the first transmit power.

The method and the telecommunication broadcasting device according to the invention have the advantage that, when a connection request is made, the telecommunication broadcasting device checks whether a wireless connection to the radio module can be established, and in the event that the wireless connection to the radio module can be established between the telecommunications transmitter and radio module wirelessly transmit signals, and the radio module transmits predetermined power signals derived from the received telecommunication transmitter signals. Therefore, there is no need for a cable connection between the telecommunications transmitter and the radio module. When arranging a radio module in a motor vehicle using a telecommunications transmission device in a motor vehicle, the driver's attention is not limited in any way by the possible gripping of the cable and thus the traffic safety is increased. In addition, a telecommunications broadcasting device can be reached by a passenger regardless of cable lengths.

A further advantage lies in the fact that a device which does not contain any radio device or contains a radio device with relatively low transmit power and which provides the required transmit power of the radio module to ensure the radio link can be used as a telecommunication transmission device. In this way, it is possible to reduce the cost of a telecommunications broadcasting device, while a single radio module for transmitting radio signals can simultaneously operate multiple telecommunication broadcasting devices, thereby further saving costs, since adequate functionality to generate the necessary broadcasting power has to be ensured once in the radio module.

If there is a relatively high predetermined power to transmit radio signals from the radio module, there will be high security of transmission of these radio signals, high range of radio signals, high call quality when transmitting speech data via radio signals, increased connection security for radio modules arranged in the marginal parts of range radio equipment associated with the relevant base stations and, when used in a motor vehicle, also increased safety of connection when driving fast. In this way, the transmission of data and faxes can also be carried out without interruption by means of radio signals when a computer unit or a fax machine is connected to the radio module or to the telecommunications transmission device.

A further advantage lies in the fact that the radio module of the various telecommunication transmitters can establish and make radio connections since the radio module is independent of the telecommunication transmitters used and can therefore be operated by different users. On the basis of this independence, it is possible to operate a telecommunications broadcasting device by means of arbitrary radio modules.

The measures set forth in the subclaims are given further advantageous embodiments and improvements of the method set forth in independent claim 1 and the telecommunications broadcasting apparatus set forth in independent claim 5.

It is particularly advantageous that, in the event that a wireless connection to the radio module cannot be established, the signals are transmitted by a telecommunications transmission device with a further predetermined power. In this way, the telecommunications transmitter can also be operated independently of the radio module, so that the telecommunications transmitter can be operated with a radio module built into, for example, a motor vehicle outside or outside the radio module, and the user needs to use radio transmission inside and outside the radio module. only one telecommunications transmission device outside the motor vehicle. This saves costs and makes it easier for the user to operate because he only has to get used to the operation of a single telecommunications broadcasting device, requiring only one authorized access card and having a single directory for the phone book.

The operation for the user is also facilitated by automatically switching the wireless connection to the radio module to transmit signals from a telecommunications transmission device with a further predetermined power.

A further advantage is that optical optical signals can be transmitted between the telecommunications transmitter and the radio module, preferably in the infrared range. In this way, there is no exposure to the user in the case of the wireless connection between the telecommunications transmitting device and the radio module. In addition, the optical exchange of data between the telecommunications transmitter and the radio module arranged in the motor vehicle has no effect on the motor vehicle electronics, which is thus not damaged in any way by the exchange of data between the telecommunications transmitter and the radio module. Thus, in a motor vehicle, a safer data exchange can be made between the telecommunications transmitter and the radio module by means of optical signals without affecting the electronics of the motor vehicle. A suitable optical interface integrated into the telecommunications transmitter will cause only insignificant weight gain and can be implemented inexpensively and with little space requirement.

A further advantage is that limited range radio signals, preferably according to the DECT-Standard (Digital Enhanced Cordless Telecommunications) standard, can be transmitted between the telecommunications transmitter and the radio module. In this way, the wireless transmission between the telecommunications transmitter and the radio module cannot be interrupted by optical obstructions.

A further advantage lies in the fact that when the wireless transmission between the telecommunications transmitter and the radio module is interrupted, signals with a further predetermined power are transmitted by the telecommunication transmitter. In this way, it is ensured that the existing connection between the telecommunication transmitter and the other radio subscriber is not interrupted when the wireless connection between the telecommunication transmitter and the radio module is interrupted, for example due to obstacles in the optical transmission path. This will therefore further increase the security of the connection.

BRIEF DESCRIPTION OF THE DRAWINGS

BRIEF DESCRIPTION OF THE DRAWINGS The invention will now be described in more detail with reference to the accompanying drawings, in which: FIG. 1 shows a block diagram of a radio module and radio equipment, and FIG. 2 is a flow chart of the process of the invention.

SK 286817-6

DETAILED DESCRIPTION OF THE INVENTION

In FIG. 1 shows a radio module 5, for example a GSM module (Global System for Mobile Communications). The radio module 5 comprises a radio transmitter unit 35 and a first interface 40 for connection to the radio transmitter unit 35. The radio transmitter unit 35 is connected to a first transceiver antenna 45. The radio transmitter unit 35 may also include a receiver unit, but is for description of this exemplary embodiment. . The first interface 40 is a wireless data exchange interface and may be formed, for example, as an optical interface or as a radio interface for limited range radio transmissions. For example, when created as an optical interface, it may be an infrared interface according to the IrDA-Standard (Infrared Data Association). For example, when designed as a radio interface for limited range radio transmissions, it may be a DECTStandard (Digital Enhanced Cordless Telecommunications) radio interface. When the first interface 40 is formed as a radio interface, a third transmit / receive antenna 55, which is shown in FIG. 1 shown in dashed lines. The first transmit / receive antenna 45 can transmit radio signals from the radio transmit unit 35 at a first predetermined power of, for example, 8 W.

For example, the radio module 5 may be connected to or integrated into the car radio. The motor vehicle antenna can then be used as the first transmit / receive antenna 45.

In FIG. 1 shows a telecommunications broadcasting device 1 designed as a radio device, for example as a GSM cellular telephone, comprising a broadcasting unit 25 which can be connected via a switch 20 to a second interface 10. The telecommunication broadcasting device 1 can also be designed as a mobile radio equipment, handheld radio equipment, operational radio equipment or the like. By means of the switch 20, the transmitting unit 25 can be further coupled to a radio unit 30 to which the second transmitting / receiving antenna 50 is connected.

The telecommunication broadcasting device 1 further comprises a monitoring device 15 to which the transmitting unit 25, the radio unit 30 and the second interface 10 are connected and which control the switch 20. The second interface 10 may be designed as an optical interface, for example an IRDA standard. However, the second interface 10 may also be designed as a radio interface for limited range radio transmissions, for example according to the DECT standard. When the second interface 10 is formed as a radio interface, a fourth transmit / receive antenna 60, which is shown in FIG. 1 shown in dashed lines.

For the telecommunications transmitter 1 to cooperate with the radio module 5, it is necessary that the first interface 40 and the second interface 10 enable wireless data exchange of the same kind, which means that both interfaces 10, 40 will be designed as optical or radio interfaces.

In FIG. 2 is a flow chart of the process of the present invention. At program point 100, the monitoring device 15 checks whether there are connection requirements. If so, it proceeds to program point 105 and otherwise returns to program point 100. Connection requests may be made by the user of the telecommunication broadcasting device 1 by selecting the called number on the input unit, which is not shown in FIG. and which is also connected to the control device 15. Then, the control device 15 controls the switch 20 to effect the connection of the transmitting unit 25 to the second interface 10 to effect wireless transmission of the dialing information to the radio module 5 and then actuate the dialing information transmission. In addition, the transmitting unit 25 may be combined with a receiving unit. Depending on the position of the switch 20, the transmitting unit 25, extended by the receiving unit, may be required to connect another radio network subscriber via the second interface 10 or the radio unit 30. In this case, the radio module 5 and the telecommunication transmission device 1 can be located in a radio apparatus connected to the base station, which in FIG. 1 is not shown a radio network that can be established according to the GSM standard. The radio data signaling the connection request of the other subscriber may be received by both the first transmit / receive antenna 45 and the second transmit / receive antenna 50. The data received by the radio unit 30 and the signaling the connection request can be detected by the control device 15. The data received by the radio The connection request signaling unit 35 of the radio module 5 may be transmitted wirelessly via the first interface 40 to the second interface 10 and also detected by the monitoring device 15.

At program point 105, the monitoring device 15 checks whether a wireless connection is possible between the first interface 40 and the second interface 10. If this is the case, it proceeds to the program point 110 and otherwise turns to the program point 125. When the request signaling data was For the connection received by the second interface 10, a check for a wireless connection between the two interfaces 10, 40 may be omitted. If a connection request has been received from the user of the telecommunications broadcasting device 1, the monitoring device 15 checks whether a confirmation signal has been received from the radio module 5 in a second time 10 in a predetermined time in response to the dialing information transmitted by the second interface 10. If so A wireless connection between the two interfaces 10, 40 is possible. 40. If the connection request signaling is received by the radio unit 30, the control device 15 first switches the switch 20 to connect the second interface 10 to the transmitting unit 25 if this connection does not already exist. and then controlling the transmitting unit 25 to transmit the polling signal via the second interface 10 to the radio module 5. Then, within a predetermined period of time, the control device 15 checks the reception of the acknowledgment signal in response to the polling signal. At program point 110, the control device 15 will operate the switch 20 to connect the second interface 10 to the transmitting unit 25 in the absence of such a connection. Thereafter, data, such as speech data, is transmitted from the transmitting unit 25 to the second interface 10 for transmission to the radio module 5, optionally after signal matching. The radio transmission unit 35 derives from the data signals of the telecommunication transmission device 1 received by the first interface 40 the radio signals it transmits with a first predetermined power via the first transmit / receive antenna 45 to the subscriber via the radio network. Data can be received by the subscriber through both the first transmit / receive antenna 45 of the radio module 5 and the second transmit / receive antenna 50 of the telecommunications transmitter 1. The signals derived from the subscriber signals received by the radio module 5 can be wirelessly transmitted from the first interface 40 to the second interface 10, and after adjustment has been carried out, further to a transmitting unit 25 extended by a receiving unit. In addition, or alternatively to a receiver unit integrated into the transmitter unit 25, a separate receiver unit may be connected to the radio unit 30 to which the subscriber signals received by the second transmit / receive antenna 50 are routed independently of the switch position 20 so that by the receiving antenna 50, the switch 20 need not be switched to connect the radio unit 30 to the transmitting unit 25 extended by the receiving unit.

At program point 115, the monitoring device 15 checks whether the connection is terminated. If this is the case, the program part will be abandoned and otherwise the program point 120 will be continued. The end of the connection can be selected by the user of the telecommunication broadcasting device 1 by, for example, controlling the handset button of the input unit not shown in FIG. 1, this control being detected by the monitoring device 15. For this purpose, the input unit may, as already mentioned, be connected to the monitoring device 15. However, the end of the connection may be selected by the subscriber with a suitably transmitted signal as well. This signal, which indicates the end of the connection, can be received by both the first transmit / receive antenna 45 and the second transmit / receive antenna 50. Upon receiving the termination signal by the first transmit / receive antenna 45 of the radio module 5, This data signal can be detected by the control device 15. However, the control device can also detect the termination signal received by the radio unit 30.

At program point 120, the monitoring device 15 checks whether the wireless data exchange between the first interface 40 and the second interface 10 is interrupted. If this is the case, there will be a branch to the program point 125 and otherwise return to the program point 110. To test the wireless data exchange between the two interfaces 10, 40, the control device 15 can activate the transmitting unit 25 to send a polling signal to the radio module 5. through the second interface 10. Previously, the control device 15 causes the switch 20 to switch the transmitting unit 25 to the second interface 10 in the absence of such a connection. If the second interface 10 does not receive a corresponding acknowledgment signal from the radio module 5 in response to the interrogation signal within a second predetermined time after the interrogation signal is transmitted, the control device 15 detects that the wireless data exchange is interrupted.

At program point 125, the control device 15 causes the switch 20 to switch the radio unit 30 to the transmitting unit 25. Transmission of radio signals to the subscriber is then carried out in the GSM radio network according to this exemplary embodiment by the second transmitting / receiving antenna 50 of the telecommunication transmitter 1. at a predetermined power, for example of 2 W. Reception of signals of the subscriber in the telecommunication transmitter 1 is possible at this program point 125 only directly via the second transmit / receive antenna 50 and the radio unit 30, and not through the second interface 10, it connects the radio unit 30 to the transmitting unit 25 and wireless data exchange is not possible directly between the two interfaces 10, 40 anyway.

From the program point 125, after the third predetermined period of time, a continuation is made to the program point 120 to allow a re-examination of the wireless data exchange via the interface 10, 40.

However, the radio unit 30 with the second transmit / receive antenna 50 need not be provided in the telecommunications transceiver 1 and the transmit unit 25 may be fixedly connected to the second interface 10. In this case, the inspection device 15 would not be necessary either. The bi-directional connection between the telecommunications broadcasting device 1 and the subscriber of the radio network connection is then only possible via the radio module 5 or both interfaces 10, 40, so that when wireless data exchange between the two interfaces 10, 40 is interrupted device 1 and the subscriber. If this disadvantage is envisaged, te can be used

The telecommunication broadcasting device 1, whose construction and functionality will be considerably simplified, which can be realized with substantial material and cost savings, so that the telecommunication broadcasting device 1 can have small dimensions.

However, the radio module 5 in any case supports the full functionality of the mobile phone and has the possibility to connect or integrate many other terminals. A fax machine or a personal computer can be additionally connected to the radio module 5 via appropriate interfaces, whether using wires or wirelessly.

The telecommunication transmission device 1 according to the invention can also be designed as a fax machine, a personal computer or the like and for carrying out the method according to the invention it can in principle have the same construction as the telecommunication transmission device 1 as a radio device according to FIG. 1. Connection of these terminals to the radio module 5 by means of conductors is therefore not necessary. When connecting or integrating the radio module 5 to the car radio or to the car radio, the functions and devices of the car radio, such as loudspeakers, sound controllers or the like, can also be used simultaneously. The radio module 5 can also cooperate with the car radio in such a way as to allow the parallel operation of radio transmission and telecommunications. For example, if there is a direct telecommunications connection, the car radio can be tuned without noise. Speaking and listening can be performed for telecommunications through the car microphone and car speakers.

By means of the first interface 40, several terminals can be operated at the same time in a suitable wireless data exchange organization by the described method according to the invention, for example by means of time-positioning methods, which may be the same or different types of terminals. The device shown in FIG. For example, multiple mobile phones can be operated simultaneously through the first interface 40. However, it is also possible to operate simultaneously mobile phones, fax machines, personal computers or the like via the first interface 40.

Furthermore, it is possible to operate the telecommunication transmission device 1 according to the invention with any number of radio modules 5 according to the invention.

When arranging radio modules in different motor vehicles, the user can therefore always be reached by a single call number, namely the telephone number of his telecommunications transmission device.

Since the radio module is independent of the terminal type and the telephone number of the telecommunications broadcasting device 1, it can be operated by different users with different terminals and terminal types.

In designing the first interface 40 and the second interface 10 as radio interfaces, only limited range radio signals are transmitted between the two interfaces 10, 40, indicating that this is a local radio check with a range that is smaller than the GSM radio network. At the same time, high transmit power is not required, so that the user is not exposed to radiation. For wireless data exchange between the two interfaces 10, 40, it is possible, for example, to select the DECT standard.

Claims (5)

PATENT CLAIMS A method of operating a telecommunications broadcasting device (1), in which, in the case of a connection request by the telecommunications broadcasting device (1), it is examined whether a wireless connection to the radio module (5) can be established, provided that the wireless connection to the radio module (5) can be formed, signals of the first transmit power are wirelessly transmitted between the telecommunication transmitter device (1) and the radio module (5), and predetermined power signals derived from the received modules are transmitted to the radio network (5) signals of the telecommunication broadcasting device (1), characterized in that when the wireless transmission between the telecommunication broadcasting device (1) and the radio module (5) is interrupted, signals with another, second predetermined power are transmitted from the telecommunication broadcasting device (1) to the radio network , and this second predetermined order no he is greater than the first transmission power. Method according to claim 1, characterized in that in the event that no wireless connection to the radio module (5) can be established, the telecommunications transmission device (1) transmits signals with a further predetermined power. Method according to claim 1 or 2, characterized in that optical signals are transmitted between the telecommunication transmission device (1) and the radio module (5), in particular in the range of infrared radiation. A telecommunication transmission device (1), in particular a radio device, characterized in that it is provided with a wireless data exchange interface (10) with a radio module (5), a transmitting unit (25), a radio unit (30). ), which is connected to a transceiver antenna (50), with a switch (20) and a control device (15) for controlling the switch (20), which is connected to the switch (20), the switch (20) being adapted to connecting the transmitting unit (25) to the interface (10) in case of possible wireless data exchange with the radio module (5) and to connect the transmitting unit (25) to the radio unit (30) in case of interrupted wireless data exchange with the radio module (5). Telecommunication transmission device (1) according to claim 4, characterized in that the interface (10) is designed as an optical interface, in particular an IrDA (Infrared Data Association) interface.