Abstract:
The invention relates to a telecommunications process with time division multiple access (TDMA) between a first and a second station, in which process one station transmits and the other receives in at least one predetermined time slot of a frame. In this process, the carrier frequency is changed over in this time slot (Z 3 ) from frame (R 1 ) to frame (R 2 ), in order, in this way, to be able to set up a plurality of transmission channels, using only one time slot. This changing over of the carrier frequency is terminated given fulfilment of an abort criterion.

Description:
BACKGROUND OF THE INVENTION 
     The invention relates to a telecommunications process with time division multiple access (TDMA) between a first and a second station, in which process one station transmits and the other receives in at least one predetermined time slot of a frame. 
     This process is a telecommunications process with time division multiple access (TDMA) between a first and a second station, in which process one station transmits and the other receives in at least one predetermined time slot of a frame. 
     In the process with time division multiple access (TDMA), the time axis is subdivided, specifically into frames which are each of the same length and have a predetermined number of bits. For example, each of these frames may be subdivided into an even number of time slots of the same size. The first half of this number of time slots within a frame is used to transmit from the transmitting first station to the receiving second station. This transmission direction is usually referred to as downlink if the first station is a base station and the second station is a mobile station. Accordingly, the second half of the number of time slots within the frame is used to transmit in the opposite transmission direction. Here, the second station transmits while the first station receives. This is usually referred to as uplink if the transmitting station is the mobile station and the receiving station is the base station. 
     Each of the aforesaid time slots is thus used to set up a transmission channel whose parameters are the number of the time slot within the frame and the carrier frequency used. In order to transmit digital data, the carrier frequency is then frequency-modulated or phase-modulated. 
     In the European DECT Standard (Digital European Cordless Telecommunications Standard), there are 24 time slots available per frame, specifically 12 in the downlink and 12 in the uplink. In contrast, in the Japanese PHS Standard (Personal Handy Phone System Standard) there are only two times four time slots available per frame, so that the number of time slots per frame is generally not very large. 
     However, many tasks may require a plurality of transmission channels with different carrier frequencies to be set up. In this case, a plurality of time slots have to be made available per frame in order to carry out the same task, so that, in terms of the number of time slots per frame, a capacity limit is quickly reached. Moreover, if, for reasons of cost, only simple synthesizers are used, the number of usable time slots is reduced further by half since these synthesizers cannot change over from one carrier frequency to another carrier frequency within the very short time period between two time slots. 
     SUMMARY OF THE INVENTION 
     The invention is based on the object of developing a telecommunications process of the type mentioned at the beginning in such a way that it permits the number of transmission channels to be increased without simultaneously requiring the use of a larger number of time slots per frame. 
     The means of achieving the object set is a set of process steps wherein the carrier frequency is changed over in the predetermined time slot from frame (R 1 ) to frame (R 2 ), and this changing over of the carrier frequency is terminated upon fulfillment of an abort criterion. 
     A telecommunications process according to the invention with time division multiple access (TDMA) between a first and a second station, in which process one station transmits and the other receives in at least one predetermined time slot of a frame, is distinguished in that 
     the carrier frequency is changed over in this time slot from frame to frame and 
     this changing over of the carrier frequency is terminated given fulfilment of an abort criterion. 
     It is thus possible to use only one time slot to set up two or more transmission channels which operate with different carrier frequencies. In this way, tasks which require the use of different transmission channels with different carrier frequencies can be carried out even if the capacity limit in terms of the number of time slots per frame is reached, for example because, with the exception of one, all the other time slots are already occupied or other time slots are subject to interference, or the like. 
     Generally, the transmitting stations are capable of detecting when the capacity in terms of the number of time slots per frame is exhausted, so that the process according to the invention does not need to be carried out continuously but is rather used only when for example, with the exception of one, all the other time slots per frame are no longer available for whatever reasons. 
     The setting up of different transmission channels which relate to the same time slot in successive frames can be carried out, for example, for the purposes of controlling the receiving station if, for this purpose, transmission has to take place at different carrier frequencies. The abort criterion can then be the expiry of a predetermined time. However, it may also be the reception of a message specifying that the changing over of the carrier frequencies be terminated. This message can be transmitted from a third station, for example. 
     A very advantageous further development of the invention is distinguished in that the first station, in the predetermined time slot, and the second station, in a further predetermined time slot of the same frame, alternately transmit and receive, and in that the carrier frequency in the further predetermined time slot is treated in the same way as that in the predetermined time slot. 
     In this context, the further predetermined time slot can advantageously be offset by half a frame length with respect to the predetermined time slot. 
     In this exemplary embodiment, there is a so-called duplex link, which requires two physical channels and which permits the subscribers to speak and listen simultaneously. In the DECT system, a time slot separation is used for duplex links. This is also referred to as Time Division Duplex (TDD). For this, time slot pairs are formed. If the first station, or base station, uses a predetermined time slot for transmission (in the downlink), the second station, or mobile station, transmits (in the uplink) in a time slot which is offset with respect to the first mentioned time slot by half a frame length. 
     According to the invention, in the case of a capacity bottleneck in terms of the number of available time slots (in the uplink) when using TDD, this second time slot is then also treated in the same way as the time slot in the downlink, which relates to the changing over of frequencies from frame to frame. In other words, when TDD is used, both time slots which are associated with one another are changed over in terms of carrier frequency from frame to frame in the downlink and in the uplink, so that different transmission channels can be set up from frame to frame for both aforesaid time slots. 
     This may be necessary if, in the uplink and in the downlink, with the exception of one time slot in each case, all the other time slots are occupied or no longer available and, for example, an intracell handover is to occur or a further transmission channel is to be set up. An intracell handover takes place if the radio channel is changed within a cell and thus with the same base station being retained. A reason for carrying out an intracell handover is if the reception level of the base station to which a link is being made at a given time is sufficiently high but the link quality is worsening severely, for example as a result of common channel interference. 
     Here, too, the abort criterion may be the expiry of a predetermined time. If no transmission channel with a sufficient level of link quality is found within the predetermined time, the link between the two stations may be interrupted. On the other hand, if a good level of link quality is achieved at one of the aforesaid frequencies, the corresponding transmission channel is definitely selected and its carrier frequency set in a stable fashion. The abort criterion would therefore in this case be the achievement of a predetermined level of transmission quality at one of the carrier frequencies. Of course, the abort criterion here may in turn also be the transmission of a message specifying that the changing over of the frequencies be terminated. 
     In principle, it would be possible, for the purpose of setting up different transmission or radio channels which relate to one time slot each, to change over the carrier frequency between only two frequency values, and specifically at least once, but preferably a plurality of times. In the latter case, a more reliable assessment of the level of link quality is possible. In this exemplary embodiment, two transmission or radio channels could therefore be assigned to one time slot in each case. 
     In a further development of the invention, the carrier frequency can however also be changed over at least once between more than two frequency values and can be either only increased or only decreased from frame to frame. With respect to a respective time slot, three or more transmission or radio channels could then be set up if required. The frequency changeover cycle, which comprises more than two carrier frequencies, can be repeated periodically here until the corresponding abort criterion has been reached. 
    
    
     BRIEF DESCRIPTION OF THE DRAWING 
     The invention is described below in more detail with reference to the drawing, in which: 
     FIG. 1 shows a frame with downlink and uplink with the carrier frequency F 3  being used in the time slots  3  and  7 ; 
     FIG. 2 shows two successive frames between which the carrier frequency for the time slots  3  and  7  has been changed over from F 3  to F 3′ ; 
     FIG. 3 shows a frame with downlink and uplink with the carrier frequency F 3  or F 3′  being used in the time slots  3  and  7 ; 
     FIG. 4 shows a software implementation of the process described in FIGS. 1 to  3 ; 
     FIG. 5 shows a switching device for changing over the carrier frequency for respective time slots in different frames; and 
     FIG. 6 shows a telecommunications system comprising base station and mobile station. 
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     With reference to FIGS. 1 to  3 , the principle on which the invention is based will be explained below in more detail with reference to a communication between a base station and a mobile station. 
     FIG. 1 shows a TDMA frame R 1  with four time slots Z 1  to Z 4  in the downlink and four time slots Z 5  to Z 8  in the uplink. During the time slot Z 3 , the base station transmits at the carrier frequency F 3 , while the mobile station is switched to reception at this time. In contrast, during the time slot Z 7  the mobile station is transmitting at the carrier frequency F 3′ , the base station now being switched to reception. F 3  is not equal to F 3′  here. 
     If, for example, an intracell handover is to take place here, specifically without using time slots other than the time slots Z 3  and Z 7  which are already in use, the carrier frequency is switched over from F 3  to F 3′  in a frame R 2 , directly following the frame R 1 , for the corresponding time slots Z 3  and Z 7 . This changeover can be continued periodically between further successive frames. This is illustrated in FIG.  2 . 
     One of the two stations, preferably the base station, then decides which of the carrier frequencies F 3  and F 3′  used should continue to be used, with a view to the best level of link quality between the two stations. This frequency is then set in a stable fashion. This can be seen in FIG.  3 . Here, the communication takes place between the base station and mobile station in time slots Z 3  and Z 7 , that is to say using either the carrier frequency F 3  or the carrier frequency F 3′ . 
     A software implementation of the process described in FIGS. 1 to  3  is shown in FIG.  4 . 
     The condition for the occurrence of this procedure is the requirement to set up a new transmission channel. Thus, in step S 1  the start of the procedure is achieved. Then, in step S 2  the carrier frequency F 3  is activated. For the first run through the procedure this is not necessary, but not incorrect either. Then, in step S 3 , the system waits until the time at which the respective time slot Z 3  is active. In step S 4 , a burst is transmitted during this time slot Z 3  at the corresponding frequency, here F 3 . In the following step S 5 , the system then waits for the next time slot Z 7  which is still in the same frame. Both time slots Z 3  and Z 7  are separated from one another by half a frame length. In step S 6 , the system attempts to receive a burst within the relevant time slot Z 7 . 
     In the subsequent step S 7 , the carrier frequency is now changed from F 3  to F 3′ . Then, the system successively runs through the steps S 8  to S 11  which correspond to the steps S 3  to S 6  but which relate to the new carrier frequency F 3′ . 
     After the step S 11  has been terminated, the abort condition is checked in step S 12 . This condition determines whether the steps S 2  to S 11  are run through again, i.e. whether the frequency F 3  is activated again in the next frame, and then F 3′  again, etc. 
     A condition for exiting from the procedure can be the expiry of a maximum time or else a result which occurs during the procedure, such as the reception of a specific information element at either frequency F 3  or F 3′ , for example. This information element can, in terms of the level of link quality, relate to the respective carrier frequencies. 
     After exiting from the procedure in step S 13 , one of the two carrier frequencies F 3  or F 3′  must be set again in a stable fashion. Thus, the carrier frequencies are used in the following order: 
     1. F 3 —starting frequency 
     2. F 3  and F 3′  alternating—temporary, virtually simultaneous use of two carrier frequencies 
     3. F 3  or F 3′ —depending on the result of the checking of the abort condition. 
     FIG. 5 shows a block circuit diagram of a switching device which permits, in a TDMA frame which comprises four time slots in the downlink and four time slots in the uplink, the frequency in the time slots  2 ,  3  and  4  to be changed over from frame to frame. 
     An RF generator  1  receives its control word from the output of a multiplexer  2  (MUX 1 ) whose address lines are controlled by a time slot counter  3 . The time slot counter  3  receives clock signals at its input Clk. With each time slot, another input of the multiplexer  2  is therefore connected through to the control input of the RF generator  1 . In the present embodiment, a specific input of the multiplexer  2  is thus fed to the input of the RF generator  1  at every fourth time slot. 
     No alternating frequency or carrier frequency is provided for the time slot  1 . Therefore, a register  4 , which contains a control word for the RF generator  1  during the first time slot is connected through directly to one of the inputs of the multiplexer  2 . The register  4  contains the control word for the carrier frequency F 1 . In the “00” state of the address lines, this control word then appears at the output of the multiplexer  2 . 
     For the other time slots it shall be possible to change over the carrier frequency at each frame. Therefore, there are two further registers  6 ,  7  and  8 ,  9  and  10 ,  11 , respectively, for each of the time slots, which registers contain the control words for the carrier frequencies assigned to the respective time slots. Thus, the control words for the carrier frequencies F 2 , F 2′  are stored in the registers  6  and  7 , the control words for the carrier frequencies F 3 , F 3′  are stored in the registers  8  and  9  and the control words for the carrier frequencies F 4 , F 4′  are stored in the registers  10  and  11 . A multiplexer  12 ,  13  and  14  is assigned in each case to a pair of registers  6 ,  7  and  8 ,  9  and  10 ,  11 , respectively. Which of the two registers of a pair is connected through to the input of the multiplexer  2  depends on the state of the LSB of a frame counter  15  which is clocked by the carry signal of the time slot counter  3 . If the LSB of the frame counter  15  is at LOW, only the respective upper registers in FIG. 5 are connected through, that is to say the registers  5 ,  6 ,  8  and  10  in succession. If, in contrast, the LSB (Least Significant Bit) is at HIGH, the respective lower registers are connected through in succession, that is to say the registers  5 ,  7 ,  9  and  11 . So that the alternating of the carrier frequency can be controlled, the LSB is not connected through directly to the address input of the multiplexers  12 ,  13  and  14  but rather directed via a gate, as a result of which the procedure can be made possible for each individual time slot. For this purpose, the output of a respective AND gate  16 ,  17  and  18  is connected to the respective address input A 0  of a respective multiplexer  12 ,  13  and  14 . In each case one input of these gates is connected to the output LSB of the frame counter  15  while the respective other input of a respective gate  16 ,  17  and  18  can receive, via a terminal A 1 , A 2  and A 3 , an enable signal, assigned to the corresponding time slot, for changing over the carrier frequency. Thus, an enable signal for changing over the frequency in the time slot Z 2  arrives at the terminal A 1 , an enable signal for changing over the frequency in the time slot Z 3  arrives at the input A 2  and an enable signal for changing over the frequency in the time slot Z 4  arrives at the input A 3 . 
     It is important that the time slot counter has twice as large a counter range as there are time slots, in order to keep the carrier frequency constant both in the transmission direction and in the reception direction so that the carrier frequency is actually not changed over until the next frame. In the embodiment illustrated, this means counting from 0 to 7 for the time slot counter  3 , i.e. not generating a transmission signal for the frame counter  15  until after the eighth time slot although only two address lines are required for addressing the inputs of the multiplexer  2 . Therefore, of the usually three outputs of the time slot counter  3 , only the two least significant outputs are used. The time slot counter  3  itself is clocked from an internal time base. 
     The circuit arrangement shown in FIG. 5 is located for example in the base station, while a corresponding circuit arrangement is also present in the mobile station. The latter circuit arrangement performs the frequency change-over in the time slots Z 5  to Z 8  and is correspondingly synchronized with the first mentioned circuit arrangement. 
     FIG. 6 also shows the rough design of the base station and mobile station which use the telecommunications process according to the invention. 
     The base station BS comprises a high-frequency component  20  which is bi-directionally connected to an antenna  19  and is designed to transmit and receive information. This high-frequency component  20  can contain the RF generator  1  shown in FIG.  5 . The high-frequency component  20  is also bi-directionally connected to a signal processing circuit  21  which contains, inter alia, the rest of the circuit shown in FIG.  5 . Moreover, the signal processing circuit  21  is connected to a processor  22  (CPU) for the operational control of the entire system. 
     The mobile station which is designed for example as a handheld apparatus HA contains a high-frequency component  24  which is connected to an antenna  23  and is bi-directionally connected to a further signal processing circuit  25 . For operational control, this signal processing circuit  25  is bi-directionally connected to a processor  26  (CPU) which itself is bi-directionally connected in each case to a keyboard  27  and to a display  28  which can also contain a field  29  for displaying text. The RF generator  1  shown in FIG. 5 may in turn be located in the high-frequency component  24 , while the rest of the circuit arrangement shown in FIG. 5 may be part of the signal processing device  25 .