FI103630B - Autonomous device control method and autonomous device - Google Patents

Description

103630

Autonomous device control method and autonomous device

Engineering

The invention relates to a method for controlling an autonomous device 5 operating on the spectrum of at least one cellular radio network and having an autonomous device having a bidirectional radio link to a subscriber terminal and automatically selecting the frequency to be used in the bidirectional radio link.

State of the art

One known radio system is the DECT system, which has a bidirectional radio link between the fixed part and the portable part. The system operates in the frequency range 15 1880 - 1900 MHz. The system has 10 carriers in use. Before use, the channel to be used for each connection is selected by dynamic channel selection. Thus, multiple DECT system devices can operate in the same area at the same time and do not interfere with each other.

20 On the other hand, operators want to take advantage of existing cellular radio networks to offer new services to their customers. It is also advantageous for the customer to be able to utilize an existing subscriber terminal while using new services. FIG. 1 illustrates autonomous devices 110, 130. The autonomous device may be a home repeater 110 or home base station 130. Home repeater 110 is bidirectional radio link 160 to cellular radio base station 100. Home repeater 110 further transmits bidirectional radio link 160 to subscriber terminal 30.

; In this way, the user 150 can move with its subscriber terminal 140 within the coverage area of its own home repeater 110. The home base station has a connection 162, for example a normal telephone connection or an ISDN connection to the public telephone network 120. The home base station 35 ma 130 transmits the connection 162 to the subscriber terminal 142 103630 2 using a two-way radio connection 172. The user 152 and its subscriber terminal 142 may move within its coverage range 130 of its home base station. In both cases, the user's connection may be cheaper than the normal 5 cellular network usage. On the other hand, the user may use his subscriber terminal as the terminal of a normal cellular radio network when leaving the coverage area of his autonomous device. The described solution offers many advantages: the user obtains the desired service at the lowest possible cost, and he / she only needs to obtain one subscriber terminal.

However, there is one major problem with the solution described, which is not present in the DECT system. The autonomous device must operate at the same frequencies as the subscriber terminal. This causes interference to radio communications between base stations 15 and subscriber terminals within the area. Also, the radio connection used by the autonomous device may be subject to interference. If the autonomous device is allowed to operate over the entire spectrum of a known cellular radio network, the interference that occurs is of a stochastic nature. This te-20 makes a good cellular radio network design very difficult, if not impossible.

Characteristics of the Invention

It is therefore an object of the present invention to provide a method that solves the problems of the prior art.

This is achieved by a method of the type disclosed in the introduction, which is characterized in that the autonomous device is controlled to use certain parts when selecting the spectral frequency of at least one cellular radio network.

The invention further relates to an autonomous device which operates on the spectrum of at least one cellular radio network and has a two-way radio link to a subscriber terminal and which automatically and dynamically selects the frequency to be used for the two-way radio link. 35 The device is characterized in that it comprises control means for directing the autonomous device to use certain parts in selecting the spectral frequency of at least one cellular radio network.

The process according to the invention achieves great benefits. The most important benefit is that interference can be eliminated. In this case, the autonomous device operates without interference and does not interfere with the radio links between base stations in the area and the subscriber terminals. Another great advantage is that the autonomous devices 10 are independent of the operator, only by performing the control function described in the method, they operate on the network of a particular operator.

The device according to the invention has the same advantages as the method described above. Preferred embodiments of the invention and other more detailed embodiments emphasize the advantages of the invention.

Explanation of the figures

In the following, the invention will be explained in more detail with reference to the examples in the accompanying drawings, in which Figure 1 shows the autonomous devices already described, Figure 2 shows the spectrum of a cellular radio network, Figure 3 shows the positioning of carriers in the cellular radio network. Figure 4 shows the operating principle of the method, Figure 5 shows an autonomous device in essential parts of the invention.

Description of Preferred Embodiments

Referring to Figure 2, one of the pre-30 signs shows the spectrum of a GSM cellular radio network. The spectrum is between 890 and 960 MHz. The uplink uses the frequency range 890-915 MHz 200. The uplink uses the frequency range 935-960 MHz 202. In practice, it should be noted that a particular operator has only 35 specific portions of the entire spectrum.

103630 4

Figure 3 shows the positioning of carriers in the spectrum of a GSM cellular radio network. The carrier spacing is 200 KHz. The first few carriers 300, 302, 304, 306, 308, 310, 312 in the uplink direction are shown in the figure.

Normally, the base station has one to two transceivers per sector of the cell. The transport capacity of one carrier is eight traffic channels.

Figure 4 illustrates the working principle of the method. The home repeater 110 has a bidirectional radio link (uplink 902.2 MHz and downlink 947.2 MHz) to base station 100 of cell 420 within 160. In addition, cells 400 (uplink 890.2 MHz and downlink 935.2) belong to the area. MHz), 402 (uplink 892.2 MHz and downlink 937.2 MHz), 404 (uplink 894.2 MHz and downlink 939.2 MHz), 406 (uplink 896.2 MHz and downlink) transmission 941.2 MHz), 408 (uplink 898.2 MHz and downlink 943.2 MHz), and 410 (uplink 900.2 MHz and downlink 2045 945.2 MHz). The home repeater 110 automatically and dynamically selects the frequency to be used for bidirectional radio communication 170. According to the method, the home repeater 110 is controlled to use certain portions 210, 220 of the spectrum 200, 202 of at least one cellular radio network. 25 liters. According to the figure, the home repeater 110 is controlled to retrieve on its bidirectional radio link 170 the most appropriate carrier frequency in the uplink between 910 and 914 MHz and the downlink between 950 and 954 MHz. Thus, interference potentials are minimized when the autonomous device 110, 130 can retrieve the frequencies it uses only for the spectrum 200, 202 of the cellular radio network that is not in use in the autonomous device 110. Certain portions of spectrum 210, 220 are determined by assigning to each portion of spectrum 355, 220 a lower limit 212, 222 and an upper limit 214, 224.

103630 5

Referring to FIG. 1, control is effected by remote control, i.e., control information is transmitted from base station 100 or a portion of the public telephone network 120 to autonomous device 110, 130 using bidirectional radio connection 160 or cable 162. Remote control 160, 162 takes place in real time. The implementation of remote control in bidirectional radio communication 160 takes place using an air interface. The authorization of the remote control 160, 162 is checked by an authentication procedure. Authentication is in accordance with known technology and is not described further here. The information obtained by remote control 160, 162 is stored in the memory 550 of the autonomous device 110, 130.

Another way to implement the control is to program the memory 550 oh-15 before activating the autonomous device 110, 130. The memory 550 of the autonomous device 110, 130 is on a separate device, for example a SIM card. The operator or vendor memorizes the boundaries of the frequency bands 212, 214, 222, 224 which the autonomous device can use to retrieve its frequency used for bidirectional radio communication 170, 172 to the subscriber terminal 140, 142.

Referring to Fig. 5, the autonomous device 110, 130 is shown in its essential parts. The autonomous device 110, 130 uses the control method described above in its operation. The autonomous device 110, 130 25 comprises an antenna 500, a duplex filter 510, a receiver 530, a transmitter 520, a user interface 560, and control means 540 for controlling the autonomous device 110, 130 to use certain portions 210, 220 of at least one cellular radio spectrum 200, 202 . The control to-30 is executed such that the control means 540 is adapted to the counter. In addition, the autonomous device 110, 130 comprises memory means 550 for storing information obtained by the remote control 160, 162. These memory means 550 may also be programmed to provide control 35 prior to commissioning of the device. The memory means 550 are, for example, a SIM card.

The invention is carried out in its simplest manner so that the steps of the method according to the invention carried out on the described devices can be converted into executable software. The software can then be stored on the memory medium 350 and executed on the control unit 340. The software then controls the operation of the means 300, 310, 320, 330, 350 and 360. On the other hand, the means required by the method according to the invention can be implemented by general or signal processors or by separate logic.

While the invention has been described above with reference to the example of the accompanying drawings, it is clear that the invention is not limited thereto but that it can be modified in many ways within the scope of this inventive idea of the appended claims.

9

Claims (19)

A method of controlling an autonomous device (110, 130), which autonomous device (110, 130) operates with at least one spectrum of cellular networks (200, 202), and which autonomous device (110, 130) has a duplex radio connection ( 170, 172) to a subscriber data terminal (140, 142), and which autonomous device (110, 130. automatically and dynamically selects the frequency to be used in the duplex radio connection (170, 172), characterized in that the autonomous device (110 , 130) is controlled to use certain portions (210, 220) of the spectrum (200, 202) in at least one cellular network when the frequency is selected. 2. A method according to claim 1, characterized in that the control is carried out by remote control (160, 162). Method according to claim 2, characterized in that the remote control (160, 162) takes place in real time. Method according to claim 3, characterized in that the remote control is carried out by using an air interface (160). 5. A method according to claim 2, characterized in that the legality of the remote control (160, 162) is checked by an authentication method. Method according to claim 2, characterized in that the information obtained with the remote control (160, 162) is stored in the memory (550) of the autonomous device (110, 130). 7. A method according to claim 1, characterized in that the particular parts of the spectrum (210) are determined by giving the respective parts of the spectrum (210, 220) a lower limit (212, 222) and an upper limit (214, 224). 103630 8. A method according to claim 1, characterized in that the control is effected by programming the memory (550) of the autonomous device (110, 130) prior to use of the device. 5 Method according to claim 6 or 8, characterized in that the memory (550) of the autonomous device (110, 130) is in a separate device. 10. A method according to claim 9, characterized in that the separate device is a SIM card. Method according to claim 1, characterized in that the autonomous device is a home base station (130). 12. A method according to claim 1, characterized in that the autonomous device is a home repeater (110). An autonomous device (110, 130) operating with at least one spectrum of the cellular network (200, 202), having a duplex radio connection (170, 172) to the subscriber data terminal (140, 142), incorrectly selects the frequency to be used in the duplex radio connection (170, 172), characterized in that the autonomous device (110, 130) comprises control means (540) for controlling the autonomous device (110, 130) ·· 25 to use certain parts (210, 220) of the spectrum (200, 202) in at least one cellular network when the frequency is selected. Device according to claim 13, characterized in that the control means (540) are arranged to receive remote control (160, 162). Device according to claim 14, characterized in that the autonomous device (110, 130) comprises memory means (550) for storing the information obtained with the remote control (160, 162). 16. Device according to claim 13, characterized in that the autonomous device (110, 130) comprises memory means (550) with which the control is implemented by programming before the device is put into operation. Device according to claim 15 or claim 16, characterized in that the memory means 5 (550) are a SIM card. Device according to claim 13, characterized in that the autonomous device is a home base station (130). 19. Device according to claim 13, characterized in that the autonomous device is a home repeater (110).