Abstract:
In a system comprising a number of base stations and a mobile station, a method for operating the mobile station. On a first radio channel, a communication is established between the mobile station and one of the base stations. It is determined whether a better radio channel is available for the communication. It is then established whether the communication is a voice or a data communication. If the communication is a data communication, it is prevented that the communication is handed over from the first channel to the better channel. Such a prevention can be maintained until the communication has ended or can be maintained for a given period of time.

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The invention relates to a method for operating a mobile phone device. Particularly, for operating in an environment that has a dynamism with respect to an actual call that comprises transmitting digital information between the device in question and a superior station, which dynamism should mandate in the mobile phone device a mode alteration of the transmitting. 
     2. Description of the Related Art 
     Present-day mobile phones are being used for transporting voice as well as digital data, and for transmitting as well as for receiving. In AMPS/NAMPS and TACS/ETACS networks a base station may request a mobile station to tune to another channel. Such other channel may become more preferable than the present one due to various dynamisms, such as a changing distance between the device and the original base station, atmospheric or other interferences, or through still further causes. In practice, when such change occurs during a fax or data call, transmission failures can readily occur that may result in loosing a part of the digital data contained in the fax or data call. It has been proposed to take measures for repairing erroneous or missing data on a relatively high level in the communication, but such will often remain unsatisfactory. 
     From a call processing point of view, the procedure to establish a call for digital transfer is exactly the same as for a normal voice call; in fact, it would be feasible to have a call that were part voice, part digital. This situation is similar from the point of view of a base station, that does not know whether a mobile station will use a call for voice or rather for data. At present, it appears to be common procedure for effecting data transfer while stopping a motor car that has the portable telephone device on board, which would diminish the dynamism. The invention however, should provides an ultimate block against data losses due to changeover to a different base station. 
     SUMMARY OF THE INVENTION 
     In consequence, amongst other things, it is an object of the invention to take simple measures for mitigating the effects of the recited dynamism to a great extent. Now therefore, according to one of its aspects the invention provides detecting of the mechanism during the actual transmitting and thereupon selectively and transiently blocking the alteration for at least a predetermined time interval. The changing of mode may pertain to searching for another base station, for another frequency on the same station, or for another change of operation parameters. 
     The invention also relates to a mobile phone device that is arranged for practising the method. Further advantageous aspects of the invention are recited in dependent claims. 
    
    
     BRIEF DESCRIPTION OF THE DRAWING 
     These and further aspects and advantages of the invention will be discussed more in detail hereinafter with reference to the disclosure of preferred embodiments, and in particular with reference to the appended Figures that show: 
     FIG. 1, a flow chart of a preferred embodiment; 
     FIG. 2, a portable device with multiple base stations; 
     FIG. 3, a changing process between two channels; 
     FIG. 4, a device setup for use with the invention. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENT 
     FIG. 1, is an exemplary flow chart of a preferred embodiment. In block  20 , the operation of the portable device is enabled, such as by actuating an ‘on’ key, detecting actuation of an arbitrary key or detecting an incoming call. In block  22 , a call is established between the device in question and an appropriate base station and generally, via that base station and another portable or stationary telephone device. Both the device and the immediate base station may have communicating facilities for voice as well as for data. In an exemplary situation, the portable device is associated to a laptop or similar relatively small-size computer, whereas the ultimate other party to the call may be associated to a stationary computer and/or data base system. In establishing the call, the portable device may have an active role or a passive one. When the call has become established, in block  24  one or more dynamisms are checked through appropriate hardware. As long as the check has a negative outcome, the system proceeds to block  30 , wherein the transmitting is continued during an appropriate time interval. After termination of this interval, it is checked in block  32  whether the call is ready and may be terminated. As long as the outcome is negative, blocks  24 ,  30  and  32  constitute a waiting loop. If the call has effectively been terminated, in block  34  the system enters a stop condition. 
     If on the other hand in block  24  the outcome had been positive, the system in block  26  checks whether actual transfer pertains to data or rather to analog signals, in particular to analog voice. If data, the system goes again to block  32 , whereby any measure to switch among base stations for mitigating effects of the dynamism is effectively blocked. Of course, things like digital error correcting through inherent coding redundancy may be undertaken. In particular, the actual base station is maintained. However, if the transfer pertains to analog signals, in particular to voice, the system goes to block  28 , and will start searching to a better base station or channel; the better channel could in principle be from the same base station. Thereafter, the call may become established on this different channel from the same or from another station. The blocking effect will then end after termination of the call in question. Alternatively, the blocking effect on the channel changing may be programmed to last only for a predetermined time: this time could be sufficient for executing certain functions, such as the transferring of a whole fax page. The changing to a better channel could then follow between two successive pages. 
     FIG. 2 shows a portable device P in an environment with multiple base stations A, B, C. Each base stations has its feasible transmission range indicated as a circle. In practice, deviations from the circular shape as well as from the uniformity among the stations may occur. Furthermore, the size or shape of a range may be influenced by atmospheric and other time-varying factors. As shown, device P should communicate with base station A. In going eastward, the device will come in a situation where both stations A and B are suitable, until finally, only station B will be useful. Translation in other directions will yield other sequences of applicable base stations. Each base station will use one or more preassigned frequency bands. Each frequency or frequency band will accommodate a limited number of calls simultaneously. Frequencies will be unique within a local set of base stations, but further away, such frequencies may be reused again. The size of the ranges will be accommodated to the maximum number of simultaneous calls, and thereby to the number of subscribers per area. The philosophy underlying the invention is that data may keep being transferred between the portable device and the base station as long as the device is within the base station&#39;s range, even if another base station would in principle give better transfer conditions. Moreover, it is supposed that the transition region is broad enough to allow completing the digital call during the moving of the device. Finally, data transfer should be more robust than voice transfer, in that each small interference with the latter may in principle be detected by a human listener, whereas data transfer may be subjected to digital data correction and various other stratagems. By way of restriction, blocking the search for a new channel or station may be effected exclusively when the portable device itself is transmitting data, but not in case the portable station is receiving data. In fact, executing such search represents an additional processing load for a portable device that usually will have only limited hardware facilities. 
     FIG. 3 illustrates a changing process between two channels, and in particular between two base stations that was published as FIG. 3 in WO 95/32594 to Umeda et al, which has the US designated. In the Figure, stage S 100  symbolizes an ongoing communication between mobile station  3  and base station  1 . In stage S 100 , entry of the mobile station into the cell or region of base station  2  is detected. In stage S 102  the cell transition is noticed to base station  1 . In stage S 103 , channel setup between base stations  1  and  2  is effected. In stage S 104 , base station  2  selects an optimum channel and in stage S 105 , starts transmission on this channel. In stage S 106  the completion of this activation is signalled to base station  1 . In stage S 107 , specification of the channel is sent to the mobile station. In stage S 108 , the synchronization with the new channel is established and the transmission is started. In stage S 109 , the reception of the new synchronization is established. In stage S 110 , the new communication takes place, and simultaneous communication through two channels takes place. The original channel may now be relinquished. Further extensive details of this procedure may be found in the body of the reference. 
     FIG. 4 shows a hardware setup of a portable device for use with the invention, in particular as shown in FIG. 1 of EP 709 977 A2 to Häkkänen et al. The received baseband signal is received in A/D converter  50 , and the samples so developed are stored in INFIFO  48 . Next, for further processing the samples are transmitted to local Digital Signal Processor  40 . The reception is synchronized by Frame Timing Control  42 , that is fed by the 16-bit wide data bus from DSP  40 . Likewise, output samples are transiently stored in OUTFIFO  44  and D/A converted in D/A converter  46  to attain the transmitted baseband signal as shown. Also here, synchronizing is by Frame Timing Control  42 . Finally, block  42  generates real-time control signals to the RF parts. For brevity, the structure of the broadcast signals nor the internal constitution of DSP  40  have been shown. 
     A particular realization for the invention is as follows: In case of AMPS or TACS/ETACS the 5-bit LOCAL information field in the message is used, as follows. If the call is a normal voice call, this field gets the value 00000. If the call is a data or fax call, this field gets the value 00001. 
     In case of a NAMPS call, a new extended Protocol message type is defined. If the call is a normal voice call, the message type is set to either 1000 0001 or to 0000 0000, depending on whether an Authentication Word C has been included or not, respectively. Such Authentication Word has been defined in the present AMPS/NAMPS specification, TIA/EIA/IS-91. On the other hand, if the call is a data/fax call, the message type is preferably set to 1000 1001 or to 0000 1000, depending on whether an authentication word has been included or not, respectively. Preferably, the mechanism is used only for outgoing calls, because it is the responsibility of the network that the call will be a data/fax call.