Patent Publication Number: US-RE40910-E

Title: Mobile communication terminal equipment usable for both satellite and terrestrial communications

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates to a mobile communication terminal equipment mountable in automobiles and other vehicles. 
     2. Description of the Prior Art 
     A variety of mobile communication systems have been developed. The middle communication systems can be roughly classified into satellite and terrestrial mobile communication systems. 
     The satellite mobile communication system is one that performs the communication among a plurality of mobile stations through an artificial satellite (and a ground base station). The satellite mobile communication system is usually organized by mobile stations mounted on various vehicles, a base station located on the ground (ground station) and an artificial satellite for wirelessly connecting the mobile stations and the base station. As such a communication system, there are known, for example, a system regulated by INMARSAT Standard M and a system INTELSAT TDMA/DSI (Time Division Multiple Access/Digital Speech Interpolation). Since almost all of the satellite mobile communication systems being currently used or planned utilize digital communication, coded voice signals, digital data and other digital signals will be handled in transmission and reception. The INTELSAT TDMA/DSI system is regulated in “Intelsat TDMA/DSI System Specification IESS-307-Rev. B”, Mar. 12, 1991. 
     The terrestrial mobile communication is one that can make the communication among a plurality of mobile stations through a ground base station and that is usually organized by mobile stations mounted in a variety of movers and base stations located on the ground. A typical terrestrial mobile communication system is a cellular system. The cellular system comprises a plurality of base stations which are arranged on the ground in a regular pattern. Each of the base stations covers a region having a given area (e.g., a circular region having a radius ranging between a few kilometers and 10 kilometers and usually being called a “cell”). Each of the base stations uses a radio frequency different from those of the other base stations covering cells which are adjacent to the first-mentioned cell. Such a system may use the minimum number of radio frequencies and more effectively utilizes the frequency resource. A typical cellular system is an automobile phone system. The cellular systems currently used are mainly of analog type, but may be shifted to digital type in the near future. A typical analog type cellular system is shown in “Cellular Mobile Telephone Equipment Specification”, May 1983, Advanced Mobile Phone Service, Inc. while a typical digital type cellular system is described in “EIA/TIA Project Number 2398”, Cellular System Dual-Mode Mobile Station-Base Station Compatibility Standard IS-54-B Revision B, Jan. 25, 1991. 
     The cellular system has a disadvantage in that it cannot be used in some areas or regions. For economy, there are areas or regions which do not have any base station and so do not belong to any cells. For example, a base station will not be provided in a country area having a low population density, a mountainous district or a depopulated area. In such an area or region, it is difficult or impossible to utilize the cellular system. 
     One method of overcoming such a problem is to mount a mobile station for cellular system with a mobile station for satellite mobile communication system in a single vehicle. If the vehicle runs in an area or region in which the cellular system can be utilized (generally, in an urban area), a user (or operator) in the vehicle can select either of the cellular or satellite mobile communication system as required. In an area or region which does not belong to any cell in the cellular system, the user cannot utilize the cellular system, but can select and use the satellite mobile communication system. 
     However, the provision of both the cellular and satellite mobile stations in a single vehicle results in an increased scale of the entire system. 
     SUMMARY OF THE INVENTION 
     It is therefore a first object of the invention to enable the continuation of communication even in an area or region which does not belong to any cell in the cellular system. 
     A second object of the invention is to reduce the entire system in size. 
     A third object is to make a part of the mobile station portable. 
     A fourth object is to suppress the heat value produced by the mobile station. 
     A fifth object is to relax restrictions relating to a place at which the mobile station is mounted in the vehicle. 
     A sixth object is to enable various configurations of communication. 
     A seventh object is to realize a more automated mobile station. 
     A eighth object is to enable the automatic selection of an antenna which can perform a more preferred reception. 
     A ninth object is to enable the preferred execution of alternating between the satellite mobile communication system and the terrestrial mobile communication system. 
     In a first aspect, the present invention provides a mobile communication terminal equipment mountable in an automobile or other vehicle, comprising:
         a) a satellite transceiver for transmitting and receiving signals through a satellite wireless communication system;   b) a terrestrial transceiver for transmitting and receiving signals through a terrestrial wireless communication system;   c) an input/output device for inputting signals from a user and for outputting signals to the user; and   d) a connection switching means for selectively connecting the input/output device to one of said satellite and terrestrial transceivers.       

     In the first aspect, the input/output device is selectively connected to one of the satellite and terrestrial transceivers. Signals from the user through the input/output device are inputted into one of the satellite and terrestrial transceivers which is connected to the input/output device. Signals received by the transceiver which is connected to the input/output device are supplied to the input/output device from which the signals are outputted to the user. 
     For example, when the satellite transceiver is connected to the input/output device, the signals inputted by the input/output device are sent to the other device (e.g., a mobile communication terminal equipment according to one of aspects of the present invention) and the signals transmitted from the other device are received by the satellite transceiver through the satellite wireless communication system. The satellite transceiver then provides the received signals to the input/output device. 
     When the terrestrial transceiver is connected to the input/output device, the signals inputted by the input/output device are transmitted from the terrestrial transceiver to the other device through the terrestrial wireless communication system. The signals transmitted from the other device are received by the terrestrial transceiver through the terrestrial wireless communication system. The terrestrial transceiver then sends the received signals to the input/output device. 
     When such a terminal equipment is mounted in a vehicle as a mobile station, the communication can be continued even in an area or region which would not be benefited from the communication system of the prior art. If the terrestrial wireless communication system is a cellular system, the satellite wireless communication system can be utilized to continue the communication even in an area or region which does not belong to any cell in the cellular system. The mobile communication terminal equipment of the present invention can be reduced in size and suppress the heat value in the mobile station since the input/output device is shared by the transceivers, in comparison with the case in which both the mobile stations for the satellite and terrestrial wireless communication systems are mounted in the same vehicle. 
     In a second aspect, the present invention provides a mobile communication terminal equipment mountable in an automobile or other vehicle, comprising:
         a) a satellite transceiver including a satellite transmission/reception circuit for transmitting and receiving signals through a satellite wireless communication system; and   b) a portable set disconnectable from the satellite transceiver so that the set can be carried by a user, said portable set comprising:
           b 1 ) a terrestrial transmission/reception circuit for transmitting and receiving signals through a terrestrial wireless communication system;   b 2 ) a signal input/output circuit for inputting signals from the user and for outputting signals to the user; and   b 3 ) a connection switching means for selectively connecting the signal input/output circuit to one of the satellite and terrestrial transmission/reception circuits.   
               

     In the second aspect, the signal input/output circuit is selectively connected to one of the satellite and terrestrial transmission/reception circuits by the connection switching means. Signals inputted from the user through the signal input/output circuit are inputted into one of the satellite and terrestrial transmission/reception circuits that is connected to the signal input/output circuit. When signals are received by one of the satellite and terrestrial transmission/reception circuits that is connected to the signal input/output circuit, these signals are then supplied to the signal input/output circuit from which they are outputted to the user. 
     In the second aspect, similarly, the communication can be continued even through an area or region which would not be benefited from the communication system of the prior art. According to the second aspect, the satellite transceiver can be reduced in size with its heat value being suppressed, since the terrestrial transmission/reception circuit is disposed within the portable set, unlike the first aspect of the present invention. The reduction of size makes it possible to reduce the restrictions on the place at which the mobile station is mounted in the vehicle. The mobile station may be located adjacent to the driver&#39;s seat, for example. 
     According to the second aspect, further, the user can carry the portable set by separating it from the satellite transceiver. The portable set can be used as a mobile station for the terrestrial wireless communication system at a position remote from the vehicle. 
     In a third aspect, the present invention provides a mobile communication system comprising:
         a) a plurality of communication terminal equipments, a first group of the equipments having a satellite wireless mobile station function of wirelessly transmitting signals to and receiving signals from a satellite base station through a satellite communication network, a second group of the equipments having a terrestrial wireless mobile station function of wirelessly transmitting signals to and receiving signals from a terrestrial base station through a terrestrial wireless communication network, a third group of the equipments having a wire terminal function of wire transmitting signals to and receiving signals from an other wire communication terminal equipment through a wire communication network, at least one of said communication terminal equipments being a mobile communication terminal equipment constructed according to the second aspect of the present invention and mounted in an automobile or other vehicle;   b) said satellite communication network interposing in the wireless transmission/reception of signals between respective one of the equipments belonging to the first group and the satellite base station;   c) said satellite base station for performing the wireless transmission/reception of signals relative to respective one of the equipments belonging to the second group through the satellite communication network and also for performing a wire transmission/reception of signals relative to the respective one of the equipments belonging to the third group and the terrestrial base station through the wire communication network;   d) said terrestrial wireless communication network interposing in the wireless transmission/reception of signals between a respective one of the equipments belonging to the second group and the terrestrial base station;   e) said terrestrial base station for performing the wireless transmission/reception of signals relative to a respective one of the equipments belonging to the second group and also for performing a wire transmission/reception of signals relative to the respective one of the equipments belonging to the third group and the satellite base station through the wire communication network; and   f) said wire communication network interposing in transmission/reception of signals among the equipments belonging to the third group, the satellite base station and the terrestrial base station.       

     According to the third aspect, a variety of configurations communication channels can be provided. This means that the third aspect provides a great variety of applications to the mobile communication terminal equipment constructed according to the second aspect of the present invention. Such communication channel configurations may be as follows:
         a) Communication terminal equipment having the satellite wireless mobile station function &lt;--&gt; satellite wireless communication network &lt;--&gt; satellite base station &lt;--&gt; satellite wireless communication network &lt;--&gt; another communication terminal equipment having the satellite wireless mobile station function.   c) Communication terminal equipment having the satellite wireless mobile station function &lt;--&gt; satellite wireless communication network &lt;--&gt; satellite base station &lt;--&gt; wire communication network &lt;--&gt; terrestrial base station &lt;--&gt; terrestrial wireless communication network &lt;--&gt; communication terminal equipment having the terrestrial wireless mobile station function.   c) Communication terminal equipment having the satellite wireless mobile station function &lt;--&gt; satellite wireless communication network &lt;--&gt; satellite base station &lt;--&gt; wire communication network &lt;--&gt; satellite base station &lt;--&gt; wire communication network &lt;--&gt; communication terminal equipment having the wire terminal function.   d) Communication terminal equipment having the terrestrial wireless mobile station function &lt;--&gt; terrestrial wireless communication network &lt;--&gt; terrestrial base station &lt;--&gt; terrestrial wireless communication network &lt;--&gt; another communication terminal equipment having the terrestrial wireless mobile station function.   e) Communication terminal equipment having the terrestrial wireless mobile station function &lt;--&gt; terrestrial wireless communication network &lt;--&gt; terrestrial base station &lt;--&gt; wire communication network &lt;--&gt; other terrestrial base station &lt;--&gt; terrestrial wireless communication network &lt;--&gt; communication terminal equipment having the terrestrial wireless mobile station function.   f) Communication terminal equipment having the terrestrial wireless mobile station function &lt;--&gt; terrestrial wireless communication network &lt;--&gt; terrestrial base station &lt;--&gt; wire communication network &lt;--&gt; communication terminal equipment having the wire terminal function.   g) Communication terminal equipment having the wire terminal function &lt;--&gt; wire communication network &lt;--&gt; another communication terminal equipment having the wire terminal function.       

     In the third aspect, at least one of the communication terminal equipments is a mobile communication terminal equipment constructed according to the second aspect of the present invention. Therefore, the third aspect also provides the same advantages provided by the second aspect. 
     The mobile communication terminal equipment according to the second aspect of the present invention includes a portable set having the terrestrial wireless mobile station function. Therefore, the aforementioned channel configurations b) and d)-f) can be realized even when the rotatable set is disconnected from the satellite transceiver. When the portable set is separated from the satellite transceiver, the user can perform the terrestrial mobile communication at a location remote from the vehicle (e.g., automobile). 
     According to the third aspect of the present invention, thus, the communication system can have a great variety of communication channel configurations since at least one of the communication terminal equipments defining the communication system is the mobile communication terminal equipment according to the second aspect of the present invention. 
     According to the second aspect of the present invention, further, the mobile communication terminal equipment can be constructed to perform the automated selection of a communication system to be utilized in response to the user&#39;s command. Thus, the mobile communication terminal equipment can more easily be used. 
     When such an arrangement is to be provided, the mobile communication terminal equipment requires a control key and its controller or command input means which can be operated by the user. The user can input various commands into the mobile communication terminal equipment through the command input means. Such commands include a command relating to the operation of the satellite transmission/reception circuit, a command relating to the operation of the terrestrial transmission/reception circuit, a command relating to the operation of the connection switching means and other commands. Particularly, the command relating to the connection switching means may include a command of selecting one of the satellite and terrestrial transmission/reception circuits when it is to be connected to the signal input/output circuit. 
     The automated selection of a communication system to be utilized in response to the user&#39;s command further requires the control of the connection switching means through terrestrial and satellite control means. For example, when a switching command of selecting and specifying the satellite transmission/reception circuit to be connected to the signal input/output circuit is given by the user, the terrestrial control means controls the connection switching means so that the satellite transmission/reception circuit will be connected to the signal input/output circuit. When a switching command of selecting and specifying the terrestrial transmission/reception circuit to be connected to the signal input/output circuit is given the satellite control means controls the connection switching means so that the terrestrial transmission/reception circuit will be connected to the signal input/output circuit. 
     The connection switching means may be composed of two switches. The first switch is used, in the transmission mode, to select one of the satellite and terrestrial transmission/reception circuits to be supplied with signals from the signal input/output circuit and in the reception mode, to select one of the satellite and terrestrial transmission/reception circuits to provide signals to the signal input/output circuit. The second switch is used to switch the control signal sending channel from one of the first channel connecting between the satellite control means and the signal input/output circuit and the second channel connecting between the terrestrial control means and the signal input/output circuit to the other. 
     The control signals carry information such as signal reception state at the satellite transmission/reception circuit, signal reception state at the terrestrial transmission/reception circuit, operation state of the connection switching means, commands from the command input means and others. These signals are transmitted and received among the satellite control means, terrestrial control means and signal input/output circuit. The satellite and terrestrial control means are responsive to control signals to control the operation of the signal input/output circuit when the corresponding one of the transmission/reception circuits is connected to the signal input/output circuit. Information provided by the control signals and control means can be visually displayed to be interpreted by the user. Information to be displayed may include the operation state of the satellite transmission/reception circuit, the signal reception state at the satellite transmission/reception circuit, the operation state of the terrestrial transmission/reception circuit, the signal reception state at the terrestrial transmission/reception circuit, the operation state of the connection switching means, the signal input/output state at the signal input/output circuit and others. 
     The transfer of control signals can be utilized to realize the selection of an antenna to be used and/or the alternating between systems. 
     In the present invention, three different types of antennas can be used:
         a) a satellite communication antenna fixedly mounted on the vehicle to perform the wireless signal transmission/reception between the communication terminal equipment and the artificial satellite;   b) a portable terrestrial communication antenna fixedly mounted on the portable set to perform the wireless signal transmission/reception relative to the base station of the terrestrial wireless communication system; and   c) a stationary terrestrial communication antenna fixedly mounded on the vehicle to perform the wireless signal transmission/reception relative to the base station of the terrestrial wireless communication system.       

     When it is wanted to perform the signal transmission/reception through the satellite wireless communication system, the satellite communication antenna is selected from among the different antennas and used. More particularly, when it is desired to utilize the satellite wireless communication system, the connection switching means is first manually or automatically controlled to connect the satellite transmission/reception circuit to the signal input/output circuit. In the signal transmission mode, the satellite control means mounded in the satellite transceiver first provides signals from the signal input/output circuit to the satellite transmission/reception circuit. The satellite transmission/reception circuit processes the signals in a predetermined manner, the processed signals being then supplied to the satellite communication antenna. The signals are transmitted from the satellite communication antenna toward the artificial satellite. On the contrary, the signal reception mode causes the satellite communication antenna to receive signals from the artificial satellite. The satellite transmission/reception circuit receives the signals from the satellite communication antenna. The satellite transmission/reception circuit processes these signals in the predetermined manner, the processed signals being then supplied to the signal input/output circuit. The signal input/output circuit outputs the signals to the user. 
     When it is wanted to perform the signal transmission/reception through the terrestrial wireless communication system, the portable or stationary terrestrial communication antenna is selected and used. Particularly, when the portable set is separated from the satellite transceiver and carried by the user or when there is no stationary terrestrial communication antenna, the portable terrestrial communication antenna must be used. Even if the stationary terrestrial communication antenna is not provided, the portability that is an important advantage of the present invention will not be damaged in any way. Therefore, the stationary terrestrial communication antenna is dispensable. When the portable set is connected to the satellite transceiver, the stationary terrestrial communication antenna can be used. In such a case, the portable terrestrial communication antenna cannot be expected to provide an excellent reception, but the stationary terrestrial communication antenna can more effectively be used. 
     When it is desired to utilize the terrestrial wireless communication system through the portable terrestrial communication antenna, the connection switching means is first manually or automatically controlled to connect the terrestrial transmission/reception circuit to the signal input/output circuit. If both the stationary and portable terrestrial communication antennas are provided, the antenna connection switching means is further manually or automatically controlled to connect the portable terrestrial communication antenna to the terrestrial transmission/reception circuit. In the signal transmission mode, the terrestrial control means mounted in the portable set causes the signal input/output circuit to send input signals to the terrestrial transmission/reception circuit. The terrestrial transmission/reception circuit processes the signals in the predetermined manner, the processed signals being then supplied to the portable terrestrial communication antenna. Thus, the signals are transmitted to, for example, the terrestrial wireless communication system through the portable terrestrial communication antenna. In the signal reception mode, the portable terrestrial communication antenna receives signals from the base station. The received signals are supplied to the terrestrial transmission/reception circuit. The terrestrial transmission/reception circuit processes the supplied signals in the predetermined manner. The terrestrial control means provides the signals processed by the terrestrial transmission/reception circuit to the signal input/output circuit. The signal input/output circuit outputs the signals to the user. 
     When it is desired to utilize the terrestrial wireless communication system through the stationary terrestrial communication antenna, the terrestrial transmission/reception circuit is similarly connected to the signal input/output circuit. In such a case, the antenna connection switching means is manually or automatically controlled to connect the stationary terrestrial communication antenna to the terrestrial transmission/reception circuit. The signal transmission/reception is similar to that of the case when the terrestrial wireless communication system is utilized through the portable terrestrial communication antenna, except that an antenna to be used is the stationary terrestrial communication antenna. 
     By selecting two or three different types of antenna, the communication can be preferably realized. Particularly, when a terrestrial communication antenna is formed by two types, namely portable and stationary, terrestrial communication antenna, the antenna connection switching means can be automatically controlled to use the stationary terrestrial communication antenna, for example, when the portable machine is connected to the satellite transceiver. In this case, the antenna connection switching means may be in the form of an antenna selecting switch which responds to a command from the terrestrial control means to select and connect one of the stationary and portable terrestrial communication antennas with the terrestrial transmission/reception circuit. 
     When the automated control of the antenna connection switching means (e.g., antenna selecting switch) is carried out for such a purpose, the satellite control means detects a potential appearing, for example, at the connection between the satellite transceiver and the portable set to judge whether or not the satellite transceiver is connected to the portable set. If the satellite transceiver is connected to the portable set, the satellite control means provides a signal indicative of this connection to the terrestrial control means. When such a signal is received by the satellite control means, the terrestrial control means controls the antenna connection switching means to connect the stationary terrestrial communication antenna to the signal input/output circuit. However, the signal input/output circuit must be connected to the terrestrial transmission/reception circuit, as an assumption. On the contrary, if the terrestrial control means does not receive a signal indicative of the connection between the satellite transceiver and the portable set from the satellite control means, the terrestrial control means controls the antenna connection switching means to connect the portable terrestrial communication antenna to the signal input/output circuit. Such an arrangement can automatically select an antenna which performs a more preferred reception. 
     In view of the fact that almost all the satellite wireless communication systems used currently and in the near future utilize digital communication, the satellite transmission/reception circuit is preferably in the form of a digital communication circuit. In such a case, signals from the signal input/output circuit are supplied to the satellite transmission/reception circuit through the satellite control means when the satellite transmission/reception circuit is connected to the signal input/output circuit. The satellite transmission/reception circuit comprises digital communication transmission and reception means. Signals are supplied from the signal input/output circuit to the transmission means. The transmission means codes the supplied signals. The coded signals and then used as modulation signals to digitally modulate transmission signals which are in turn supplied to the satellite communication antenna. The signals received by the satellite communication antenna are digitally demodulated and decoded by the reception means. The satellite control means provides the decoded signals to the signal input/output circuit when in turn outputs them to the user. 
     A typical terrestrial wireless communication system currently used in an analog cellular system. If the mobile communication terminal equipment of the present invention is to be used in such a type of system, the terrestrial transmission/reception circuit is in the form of an analog communication circuit. In this case, when the terrestrial transmission/reception circuit is connected to the signal input/output circuit, signals from the signal input/output circuit are supplied to the terrestrial transmission/reception circuit through the terrestrial control means. The terrestrial transmission/reception circuit comprises analog communication transmission and reception means. Signals are provided from the signal input/output circuit to the transmission means. The transmission means uses the supplied signals as modulation signals to analog modulate transmission signals which are in turn sent to the portable or stationary terrestrial communication antenna. The signals received by the portable or stationary terrestrial communication antenna are analog demodulated and decoded by the reception means. The terrestrial control means supplied the decoded signals to the signal input/output circuit which outputs the signals to the user. 
     When the mobile communication terminal equipment of the present invention is to be used in the digital cellular system, the terrestrial transmission/reception circuit is in the form of a digital communication circuit. In this case, when the terrestrial transmission/reception circuit is connected to the signal input/output circuit, signals from the signal input/output circuit are fed to the terrestrial transmission/reception circuit through the terrestrial control means. The terrestrial transmission/reception circuit comprises digital communication transmission and reception means. Signals from the signal input/output circuit are supplied to the transmission means. The transmission means codes the supplied signals. The coded signals are used as modulation signals to subject transmission signals to the digital modulation, the modulated signals being then supplied to the portable or stationary terrestrial communication antenna. The received signals are then digitally demodulated and decoded by the reception means. The terrestrial control means sends the decoded signals to the signal input/output circuit which in turn outputs these signals to the user. 
     The alternating between the satellite mobile communication system and the terrestrial mobile communication system can be preferably executed by utilizing the control signals. In such a case, the satellite and terrestrial control means monitor the signal reception state at the satellite or terrestrial transmission/reception circuit. When the portable set is connected to the satellite transceiver, the terrestrial control means informs the satellite control means of the monitored result. The satellite control means compares a signal reception state at the satellite transmission/reception circuit and a signal reception state at the terrestrial transmission/reception circuit which is taught by the terrestrial control means with a predetermined reference condition. The reference condition may be either of a reception level (in the analog and digital communications) or an error rate (in the digital communication). The reception level or error rate must be preset to the satellite and terrestrial transmission/reception circuits, respectively. The satellite control means executes different operations depending on the comparison result. 
     If the result is such that the signal reception state at the terrestrial transmission/reception circuit is sufficient to continue the signal reception at the terrestrial transmission/reception circuit, the satellite control means controls the connection switching means to connect the terrestrial transmission/reception circuit with the signal input/output circuit. Such an operation may be executed by the satellite control means solely or in cooperation with the terrestrial control means. If the result is such that the signal reception state at the terrestrial transmission/reception circuit is not sufficient to continue the signal reception at the terrestrial transmission/reception circuit, but that the signal reception state at the satellite transmission/reception circuit provides a relatively good reception state if the signals are received by the satellite transmission/reception circuit, the satellite control means controls the connection switching means to connect the satellite transmission/reception circuit with the signal input/output circuit. This operation may similarly be executed by the satellite control means solely or in cooperation with the terrestrial control means. 
     If the terminal equipment of the present invention is to be used in a voice communication, the signal input/output circuit may include a microphone for inputting voice signals from the user and loudspeakers for outputting voice signals to the user. The connection between the satellite transmission/reception circuit and the portable set may be performed by an electrically connectable/disconnectable connector. In this case, one of the communications through the satellite and terrestrial wireless communication systems can be selected and executed when the connector of the satellite transceiver is electrically connected to the connector of the portable set. When the connector of the satellite transceiver is electrically disconnected from the connector of the portable set, the mobile communication terminal equipment can perform the communication through the terrestrial wireless communication system. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a conceptual view of a vehicle in which the first embodiment of a mobile communication terminal equipment constructed in accordance with the present invention is mounted, particularly showing the layout of units in the vehicle. 
         FIG. 2  is a block diagram of the mobile communication terminal equipment shown in  FIG. 1 , showing the flow of transmitted and received signals by solid lines and the flow of control signals by broken lines. 
         FIG. 3  is a system chart of an environment in which the mobile communication terminal equipment shown in  FIG. 1  is used. 
         FIG. 4  is a conceptual view of a vehicle in which the second embodiment of a mobile communication terminal equipment constructed in accordance with the present invention is mounted, particularly showing the layout of units in this vehicle. 
         FIG. 5  is a block diagram of the mobile communication terminal equipment shown in  FIG. 4 , showing the flow of transmitted and received signals by solid lines and the flow of control signals by broken lines. 
         FIG. 6  is a conceptual view of a vehicle in which the third embodiment of a mobile communication terminal equipment constructed in accordance with the present invention is mounted, particularly showing the layout of units in this vehicle. 
         FIG. 7  is a block diagram of the mobile communication terminal equipment shown in  FIG. 6 , showing the flow of transmitted and received signals by solid lines and the flow of control signals by broken lines. 
         FIG. 8  is a system chart of an environment in which the mobile communication terminal equipment shown in  FIG. 6  is used. 
         FIG. 9  is a conceptual view of a vehicle in which the fourth embodiment of a mobile communication terminal equipment constructed in accordance with the present invention is mounted, particularly showing the layout of units in this vehicle. 
         FIG. 10  is a block diagram of the mobile communication terminal equipment shown in  FIG. 9 , showing the flow of transmitted and received signals by solid lines and the flow of control signals by broken lines. 
         FIG. 11  is a system chart of an environment in which the mobile communication terminal equipment shown in  FIG. 9  is used. 
         FIG. 12  is a conceptual view of a vehicle in which the fifth embodiment of a mobile communication terminal equipment constructed in accordance with the present invention is mounted, particularly showing the layout of units in this vehicle. 
         FIG. 13  is a block diagram of the mobile communication terminal equipment shown in  FIG. 12 , showing the flow of transmitted and received signals by solid lines and the flow of control signals by broken lines. 
         FIG. 14  is a system chart of an environment in which the mobile communication terminal equipment shown in  FIG. 12  is used. 
         FIG. 15  is a conceptual view of a vehicle in which the sixth embodiment of a mobile communication terminal equipment constructed in accordance with the present invention is mounted, particularly showing the layout of units in this vehicle. 
         FIG. 16  is a block diagram of the mobile communication terminal equipment shown in  FIG. 15 , showing the flow of transmitted and received signals by solid lines and the flow of control signals by broken lines. 
         FIG. 17  is a system chart of an environment in which the mobile communication terminal equipment shown in  FIG. 15  is used. 
         FIG. 18  is a conceptual view of a vehicle in which the seventh embodiment of a mobile communication terminal equipment constructed in accordance with the present invention is mounted, particularly showing the layout of units in this vehicle. 
         FIG. 19  is a block diagram of the mobile communication terminal equipment shown in  FIG. 18 , showing the flow of transmitted and received signals by solid lines and the flow of control signals by broken lines. 
         FIG. 20  is a system chart of an environment in which the mobile communication terminal equipment shown in  FIG. 18  is used. 
         FIG. 21  is a view illustrating the hand-off or alternating between different systems, which is executed by the mobile communication terminal equipment shown in FIG.  18 . 
         FIG. 22  is a conceptual view of a vehicle in which the eighth embodiment of a mobile communication terminal equipment constructed in accordance with the present invention is mounted, particularly showing the layout of units in this vehicle. 
         FIG. 23  is a block diagram of the mobile communication terminal equipment shown in  FIG. 22 , showing the flow of transmitted and received signals by solid lines and the flow of control signals by broken lines. 
         FIG. 24  is a system chart of an environment in which the mobile communication terminal equipment shown in  FIG. 22  is used. 
     
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     Some preferred embodiments of the present invention will now be described. It is to be understood that parts having the same function or placed in the corresponding relationship relative to one another are denoted by the same reference numeral throughout the illustrated embodiments. 
     (1) First Embodiment 
       FIGS. 1-3  show the first embodiment of the present invention. 
     As shown in  FIG. 1 , a mover M includes a satellite communication antenna  1  and cellular antenna  2  which are mounted thereon at a place having a fine view, for example, on the roof of the vehicle M when it is an automobile. The satellite communication antenna  1  is used to perform the communication with the other communication terminal equipment through an artificial satellite and a ground station for satellite communication system. The cellular antenna  2  is used to make the communication with the other communication terminal equipment through a ground station in a cellular system. These antennas  1  and  2  are connected to a transceiver unit  3 . The transceiver unit  3  may be disposed within the interior of the vehicle M, for example, the trunk of an automobile. The transceiver unit  3  has functions of handling and controlling the wireless communication. The transceiver unit  3  is also connected to a hand set  4  which has functions of inputting commands from the user, displaying states of the terminal equipment and communication channels and inputting/outputting voice signals. 
     As shown in  FIG. 2 , the transceiver unit  3  comprises a satellite communication transceiver  5 , a cellular transceiver  10  and a switch  17 . The satellite communication transceiver  5  is necessary when using the satellite communication system (satellite mode) and therefore the satellite communication antenna  1  is connected to the transceiver  5 . The cellular transceiver  10  is necessary when using the cellular system (cellular mode) and therefore the cellular antenna  2  is connected to the transceiver  10 . The switch  17  is means for selectively connecting the hand set  4  to one of the transceivers  5  and  10 . The switch  17  is controlled by the transceivers  5  and  10 . 
     The satellite mode wireless communication processing function is mainly realized by the satellite communication transceivers  5 , a part of which is also realized by the satellite communication antenna  1 . It is of course possible that all these functions may be included in the satellite communication transceiver  5 . The satellite communication transceiver  5  comprises a frequency converter  6 , a base band circuit  7 , a voice codec  8  and a controller  9 . The satellite communication antenna  1  comprises an antenna body  1 a, a diplexer  1 b, a high-power amplifier  1 c for transmission and a low-noise amplifier  1 d for reception. 
     When the hand set  4  is connected to the satellite communication transceiver  5  through the switch  17 , voice signals (transmission signals) and control signals are supplied from the hand set  4  to the satellite communication transceiver  5  through the switch  17  while voice signals (reception signals) and control signals are provided from the satellite communication transceiver  5  to the hand set  4  through the switch  17 . 
     The signal transmitting function of the satellite communication transceiver  5  will be realized as follows: 
     Voice signals of the signals supplied from the hand set  4  to the satellite communication transceiver  5  through the switch  17  are first inputted into the voice codec  8 , with a part of control signals being also inputted into the voice codec  8 . The other control signals are inputted into the controller  9 . The signals inputted into the voice codec  8  are coded according to a predetermined coding rule, the coded signals being then inputted into the base band circuit  7 . The base band circuit  7  subjects these signals to base band processing steps such as modulation and others, the processed signals being then inputted into the frequency converter  6 . The frequency converter  6  converts the frequency of the received signals from the base band frequency into a radio frequency, the converted signals being then supplied to the highpower transmission amplifier  1 c. The high-power transmission amplifier  1 c amplifies and sends the signals to the antenna body  1 a through the diplexer  1 b. Thus, the signals will be transmitted through the antenna. Such a digital communication process is carried out because the satellite communication system handled by the first embodiment is a digital communication system. 
     The signal reception function of the satellite communication transceiver  5  will be realized as follows: 
     Signals of radio frequency received by the antenna body  1 a are first inputted into the low-noise reception amplifier  1 d through the diplexer  1 b. The low-noise reception amplifier  1 d low-noise amplifies and sends the signals to the frequency converter  6 . The frequency converter  6  converts the frequency of the inputted signals from the radio frequency into the base band frequency, the converted signals being then sent to the base band circuit  7 . The base band circuit  7  subjects the signals to the base band processing steps such as demodulation and the others before they are inputted into the voice codec  8 . The voice codec  8  decodes the signals in accordance with the coding rule, the decoded signals being then fed to the hand set  4  through the switch  17 . 
     The controller  9  responds to the control signals from the hand set  4  to control the parts of the satellite communication transceiver  5  while monitoring the states of the parts of the satellite communication transceiver  5  and the signal reception station thereof. As will be described, the controller  9  controls the switch  17  and hand set  4  depending on the control signals and monitoring results. 
     The cellular mode wireless communication processing function will be realized by the cellular transceiver  10 . The cellular transceiver  10  comprises a diplexer  11 , a high-power amplifier  12  for transmission, a low-noise amplifier  13  for reception, a frequency converter  14 , a modulator/demodulator  15  and a controller  16 . 
     When the hand set  4  is connected to the cellular transceiver  10  through the switch  17 , voice signals (transmission signals) and control signals are supplied from the hand set  4  to the cellular transceiver  10  through the switch  17  while voice signals (reception signals) and control signals are provided from the cellular transceiver  10  to the hand set  4  through the switch  17 . 
     The signal transmission function of the cellular transceiver  10  will be realized as follows: 
     Voice signals of the signals supplied form the hand set  4  to the cellular transceiver  10  through the switch  17  are inputted into the modulator/demodulator  15 , with some of the control signals also being inputted into the modulator/demodulator  15 . The other control signals are inputted into the controller  16 . The modulator/demodulator  15  modulates carriers by using the receive signals as analog modulation signals and the modulated carriers are in turn sent to the frequency converter  14 . The frequency converter  14  converts the frequency of the signals from the base band frequency into the radio frequency, the converted signals being fed to the high-power transmission amplifier  12 . The high-power transmission amplifier  12  amplifies the power of the signals, the amplified signals being supplied to the antenna  2  through the diplexer  11 . Thus, the signals will be transmitted through the antenna  2 . The analog communication process is carried out because the cellular system handled by the first embodiment is an analog communication system. 
     The signal reception function of the cellular transceiver  10  will be realized as follows: 
     Signals of radio frequency received by the antenna  2  are first inputted into the low-noise reception amplifier  13  through the diplexer  11 . The low-noise reception amplifier  13  low-noise amplifies and sends the signals to the frequency converter  14 . The frequency converter  14  converts the frequency of the inputted signals from the radio frequency into the base band frequency, the converted signals being then sent to the modulator/demodulator  15 . The modulator/demodulator  15  demodulates the voice signals and control signals from the reception signals and the demodulated signals are in turn supplied to the hand set  4  through the switch  17 . 
     The controller  16  responds to the control signals from the hand set  4  to control the parts of the cellular transceiver  10  while monitoring the states of the parts of the cellular transceiver  10  and the signal reception state thereof. As will be described, the controller  16  controls the switch  17  and hand set  4  depending on the control signals and monitoring results. 
     The transceiver unit  3  is connected to the hand set  4  through connectors  29  and  28 . In other words, the voice and control signals handled through the switch  17  are supplied to the hand set  4  through the connectors  29  and  28 . The hand set  4  has a display controller  18 , an operation key controller  19 , a microphone  20 , loudspeakers  21  and an interface  22 . 
     The microphone  20  serves as means for inputting voice signals to be transmitted. Voice signals from the microphone  20  are fed to the transceiver unit  3  through the interface  22 . In the satellite mode, the voice codec  8  receives the voice signals through the switch  17  while in the cellular mode, the modulator/demodulator  15  receives the voice signal through the switch  17 . 
     The loudspeakers  21  serve as means for converting and outputting the received voice signals into sound. In the satellite mode, the voice signals are outputted from the voice codec  8  to the loudspeakers  21  through the switch  17  and interface  22  while in the cellular mode, the voice signals are outputted from the modulator/demodulator  15  to the loudspeakers  21  through the switch  17  and interface  22 . 
     The operation key controller  19  serves as means for inputting commands from the user to the terminal equipment and comprises a panel including a plurality of operation keys and a controlling function. Commands from the operation key controller  19  are supplied to the transceiver unit  3  through the interface  22  as control signals. In the satellite mode, the transceiver  5  receives the control signals while in the cellular mode, the transceiver  10  receives the control signals. At least some of the inputted control signals are inputted into the controller  9  or  16 . The controller  9  or  16  responds to the inputted control signals to control the parts of the transceiver  5  or  10 . If the inputted control signals indicate the alternating from the satellite mode to the cellular mode and vice versa, the controller  9  or  16  received the control signals provides a control signal to the switch  17  which will thus connect the transceiver  10  or  5  to the hand set  4 . 
     The display controller  18  displays the necessary information depending on the control signals from the controller  9  or  16 . For example, the information may include the signal reception state, the operational state of the system, the selected mode and other data. 
     According to the first embodiment, therefore, the satellite wireless communication system can be utilized to continue the communication even at an area and/or region which do not belong to any cell in the cellular system. Since the hand set  4  is shared by both the satellite and cellular communication systems, the entire structure can be reduced in size with the heat value being suppressed, in comparison with a case when the mobile station functions of the satellite and cellular communication systems are simply combined. 
     The system of the first embodiment may be used, for example, in such an environment as shown in FIG.  3 .  FIG. 3  shows four vehicles M 1 -M 4 . Terminal equipments constructed according to the first embodiment are mounted in the vehicles M 1  and M 2 . The vehicle M 3  only includes a satellite communication terminal equipment while the vehicle M 4  only includes a cellular terminal equipment. The terminal equipments mounted in the vehicles M 1 -M 3  can be connected to a ground station BS 1  in a satellite communication system through a radio transmission channel R 1 , an artificial satellite S and a radio transmission channel R 3  while the terminals of the vehicles M 1 , M 2  and M 4  can be connected to a base station BS 2  of a cellular system through a radio transmission channel R 2 . The ground and base stations BS 1 , BS 2  are further connected to a public telephone line T 1  or T 2  through an exchanger EX 1  or EX 2 . The public telephone lines T 1  and T 2  are connected to a general telephone set. The exchangers EX 1  and EX 2  are connected to each other through a public telephone line T 3 . 
     Therefore, this embodiment can perform the communication through new channels as follows:
         a) M 1 &lt;--&gt;R 1 &lt;--&gt;S&lt;--&gt;R 3 &lt;--&gt;BS 1 &lt;--&gt;R 3 &lt;--&gt;S&lt;--&gt;R 1 &lt;--&gt;M 2     b) M 1 &lt;--&gt;R 2 &lt;--&gt;BS 2 &lt;--&gt;R 2 &lt;--&gt;M 2 &lt;--&gt;   c) M 1 &lt;--&gt;R 1 &lt;--&gt;S&lt;--&gt;R 3 &lt;--&gt;BS 1 &lt;--&gt;T 3 &lt;--&gt;BS 2 &lt;--&gt;R 2 &lt;--&gt;M 2     d) M 1 &lt;--&gt;R 2 &lt;--&gt;BS 2 &lt;--&gt;T 3 &lt;--&gt;BS 1 &lt;--&gt;R 3 &lt;--&gt;S&lt;--&gt;R 1 &lt;--&gt;M 2     e) M 1  or M 2 &lt;--&gt;R 1 &lt;--&gt;S&lt;--&gt;R 3 &lt;--&gt;BS 1 &lt;--&gt;R 3 &lt;--&gt;S&lt;--&gt;R 1 &lt;--&gt;M 3     f) M 1  or M 2 &lt;--&gt;R 2  &lt;--&gt;BS 2 &lt;--&gt;T 3 &lt;--&gt;BS 1 &lt;--&gt;R 3 &lt;--&gt;S &lt;--&gt;R 1 &lt;--&gt;M 3     g) M 1  or M 2 &lt;--&gt;R 2 &lt;--&gt;BS 2 &lt;--&gt;R 2 &lt;--&gt;M 4     h) M 1  or M 2 &lt;--&gt;R 1 &lt;--&gt;S&lt;--&gt;R 3 &lt;--&gt;BS 1 &lt;--&gt;T 3 &lt;--&gt;BS 2 &lt;--&gt;R 2 &lt;--&gt;M 4     i) M 1  or M 2 &lt;--&gt;R 1 &lt;--&gt;S&lt;--&gt;R 3 &lt;--&gt;BS 1 &lt;--&gt;T 1 &lt;--&gt;T   j) M 1  or M 2 &lt;--&gt;R 2 &lt;--&gt;BS 2 &lt;--&gt;T 2 &lt;--&gt;T       

     For example, the communication may be carried out between the vehicles M 1  and M 2  through one or four channels a)-d). The communication may be made between the vehicles M 1  or M 2  and M 4  through one of two channels e) and f). The communication may be performed between the vehicle M 1  or M 2  and the general telephone set T through one of two channels i) and j). Although only a single ground base station is shown in  FIG. 3 , a plurality of such stations may actually be provided. It is therefore obviously possible that bypass channels h′) and j′) from any vehicle to a base station BS 2  responsible for the other cells may be routed through the public telephone line. 
     The prior art can only provide three channels as follows: 
     k) M 3 &lt;--&gt;R 1 &lt;--&gt;S&lt;--&gt;R 23 &lt;--&gt;BS 1 &lt;--&gt;T 3 &lt;--&gt;BS 2 &lt;--&gt;R 2 &lt;--&gt;M 4   
     l) M 3 &lt;--&gt;R 1 &lt;--&gt;S&lt;--&gt;R 3 &lt;--&gt;BS 1 &lt;--&gt;T 1 &lt;--&gt;T m) M 4 &lt;--&gt;R 2 &lt;--&gt;BS 2 &lt;--&gt;T 2 &lt;--&gt;T 
     Such a great number of channels are realized by providing a single vehicle in which the mobile stations of both the satellite and cellular communication systems are mounted together. 
     (2) Second Embodiment 
       FIGS. 4 and 5  show the second embodiment of the present invention. In this embodiment, the transceiver unit  3  of the first embodiment is replaced by a transceiver unit  3 A which utilizes a base band circuit  7 A and voice codec  8 A in place of the modulator/demodulator  15 . Therefore, the second embodiment can be applied to a digital cellular system. The other parts and advantages are similar to those of the first embodiment. 
     (3) Third Embodiment 
       FIGS. 6-8  show the third embodiment of the present invention. 
     The third embodiment includes an independent transceiver  5 A which has the satellite wireless communication processing function separated from the other functions of the transceiver unit  3  in the first embodiment. The third embodiment also includes a hand set  24  which has the cellular wireless communication processing function together with such functions as in the hand set  4  of the first and second embodiments. The transceiver  5 A can be releasably connected to the hand set  24  through connectors  28  and  29 . For such a purpose, the cellular antenna  2  in the first and second embodiments is replaced by a cellular antenna  25  which is arranged at the hand set  24 . The cellular antenna  25  is one that performs the communication with the other communication terminal equipments through the ground station BS 2  of the cellular system, as in the cellular antenna  2  of the first and second embodiments. The transceiver  5 A may be disposed in the vehicle adjacent to its driver seat if the vehicle is an automobile. 
     As shown in  FIG. 7 , the third embodiment further includes switches  26  and  27  in place of the switch  17 . The switches  26  and  27  are mounted in the hand set  24 . The switch  26  responds to a command from the controller  9  or  16  to connect the voice codec  8  in the satellite mode or the modulator/demodulator  15  in the cellular mode to the microphone  20  and loudspeakers  21  through the interface  22 . The other switch  27  responds to a command from the controller  9  or  16  to connect the controller  9  in the satellite mode or the controller  16  in the cellular mode with the amplifiers  12  and  13 , frequency converter  14 , modulator/demodulator  15 , display controller  18 , operating key controller  19  and other components through the interface  22 . Thus, the controller  9  performs the control of the voice signal processing and the system operation in the satellite mode while the controller  16  performs this control in the cellular mode. The controllers  9  and  16  are connected to each other through the connectors  28  and  29 . 
     The changing over of the switches  26  and  28  is made on providing a command from the user through the operation key controller  19 . 
     It is now assumed that the connectors  28  and  29  are connected to each other and the terminal equipment is in the satellite mode. The interface  22  is connected to the voice codec  8  and controller  9  through the switches  26  and  27 , respectively. If a command of switching the satellite mode into the cellular mode is provided from the operation key controller  19  in such a situation, the command is inputted into the controller  9  through the switch  27 . In response to this command, the controller  9  instructs, to the controller  16 , that the switches  26  and  27  should be shifted, through the connectors  28  and  29 . In response to this command, the controller  16  switches the switches  26  and  27  into the sides of the modulator/demodulator  15  and controller  16 , respectively. 
     It is next assumed that the connectors  28  and  29  are connected to each other and that the terminal equipment is in the cellular mode. The interface  22  is connected to the sides of the modulator/demodulator  15  and controller  16  through the switches  26  and  27 , respectively. When a command of switching the cellular mode into the satellite mode is provided from the operation key controller  19 , this command is inputted into the controller  16  through the switch  27 . The controller  16  responds to the command to switch the switches  26  and  27  into the sides of the voice codec  8  and controller  9 , respectively. 
     If the connectors  28  and  29  are disconnected from each other when the terminal equipment is in the satellite mode, the conntroller  16  knows this fact through the connectors  28  and  29 . For example, if one of the terminals defining the connector  29  is grounded at the side of the transceiver  5 A, the above fact can be known when the controller  16  detects that the potential of a terminal of the connector  28  corresponding to the grounded terminal of the connectors  29  is made open. The controller  16  responds to this detection to switch the switches  26  and  27  into the sides of the modulator/demodulator  15  and controller  16 , respectively. 
     If the connectors  27  and  28  are disconnected from each other when the terminal equipment is in the cellular mode, the cellular mode cannot be shifted to the satellite mode, but the communication can be carried out in the cellular mode. 
     According to the third embodiment, therefore, the structure of a fixed part (transceiver  5 A) within the vehicle M can be further reduced in size with the heat value thereof being suppressed, in addition to the advantages similar to those of the first embodiment. Since all the components relating to the cellular system are included in the hand set  24 , the transceiver  5 A is reduced in size and may be arranged adjacent to the driver seat in the automobile. 
     In this embodiment, the hand set  24  can be released and carried by the user. The first and second embodiments cannot perform the communication when the hand set  4  is disconnected from the transceiver unit  3 . However, the third embodiment can use the hand set  4  in the cellular mode even when it is disconnected from the transceiver unit  5 A. As shown in  FIG. 8 , thus, the user U can utilize the cellular terminal function through an increased number of communication channels when he or she is at a location remote from a vehicle M 5  in which the terminal equipment of the third embodiment is mounted. 
     Since the change of mode from the satellite mode to the cellular mode or vice versa can automatically be carried out depending on a command from the operation key controller  19  in the third embodiment, the usability can be greatly improved. The usability can be further improved by detecting the disconnection of the connectors  28  and  29  to make the automatic change of mode. 
     (4) Fourth Embodiment 
       FIGS. 9-11  show the fourth embodiment of the present invention in which a hand set  24 A is substituted for the hand set  24  in the third embodiment. The hand set  24 A utilizes a base band circuit  7 A and voice codec  8 A in place of the modulator/demodulator  15 . Therefore, the fourth embodiment can be applied to the digital cellular communication. The other components and advantages are similar to those of the third embodiment. 
     (5) Fifth Embodiment 
       FIGS. 12-14  show the fifth embodiment of the present invention in which cellular antenna  2  and switch  30  are further provided in addition to the arrangement of the third embodiment. The cellular antenna  2  is located on a vehicle M at a fine view place. The structure and function of a transceiver  5 B are substantially the same as in the transceiver  5 A, but different in that the transceiver  5 B is connected to the cellular antenna  2 . The structure and function of the hand set  24 B are substantially the same as in the hand set  24 , but different in that the hand set  24 B includes the switch  30 . The cellular antenna  2  is connected to the connector  29  through the interior of the transceiver  5 B and also to the switch  30  through the connector  28 . The switch  30  is one for selectively connecting the diplexer  11  to one of the antennas  25  and  2 . The switch  30  is controlled by the controller  16 . The controller  16  also has a function which is provided by the interface  22  of the third embodiment. 
     The functions of the fifth embodiment are similar to those of the third embodiment except the automatic antenna selection function thereof. When the connectors  28  and  29  are disconnected from each other, the antenna  25  is automatically connected to the diplexer  11 . When the connectors  28  and  29  are connected to each other in the cellular mode, the antenna  2  is connected to the diplexer  11 . 
     It is now assumed that the connectors  28  and  29  are disconnected from each other and that the system is used in the cellular mode. Under such a condition, the switches  26 ,  27  and  30  are in connection to the modulator/demodulator  15 , controller  16  and antenna  25 , respectively. When the connectors  28  and  29  are connected to each other under such a condition, it is detected by the controller  9 . If one of the terminals defining the connector  28  has been grounded, the above detection can be accomplished by detecting the open potential of a terminal of the connector  29  corresponding to the grounded terminal of the connector  28 . In response to the detection, the controller  9  produces and gives a command of actuating the switch  30  to the controller  16  through the connectors  28  and  29 . In response to this command, the controller  16  causes the switch  30  to shift to the side of the antenna  2 . When the connectors  28  and  29  are connected to each other, therefore, the terminal equipment can be switched to the antenna  2  which is located in the vehicle M at the fine view place. This can improve the signal transmission and reception quality. Since the switching is automatically made, the user U does not have to make any operations to select one of the antennas  2  and  25 . 
     It is now assumed that the connectors  28  and  29  are connected to each other and that the equipment is used in the cellular mode. Under such a condition, the switches  26 ,  27  and  30  are in connection with the sides of the modulator/demodulator  15 , controller  16  and antenna  2 , respectively. If the connectors  28  and  29  are disconnected from each other, it is detected by the controller  16 . If one of the terminals defining the connector  29  has been grounded, the detection can be accomplished by detecting the open potential of a terminal of the connector  28  which corresponds to the grounded terminal of the connector  29 . In response to this detection, the controller  16  shifts the switch  30  to the side of the antenna  25 . Therefore, the antenna  25  can be selected by disconnecting the connectors  28  and  29  from each other. Since the switching is automatically carried out, the user U does not have to make any operations to activate the switch  30 . 
     The fifth embodiment can also provide the same advantages as in the third embodiment. 
     (6) Sixth Embodiment 
       FIGS. 15-17  show the sixth embodiment of the present invention in which the hand set  24 B of the fifth embodiment is replaced by a hand set  24 C. The hand set  24 C utilizes a base band circuit  7 A and voice codec  8 A in place of the modulator/demodulator  15 . Therefore, the sixth embodiment can be applied to the digital cellular communication. The other components and advantages are similar to those of the fifth embodiment. 
     (7) Seventh Embodiment 
       FIGS. 18-21  show the seventh embodiment of the present invention which utilizes a hand set  24 D having the functions of the controller  16  different from those of the hand set  24  in the third embodiment and also a transceiver  5 C having the functions of the controller  9  different from those of the transceiver  5 A in the third embodiment. The other components, functions and advantages are similar to those of the third embodiment. 
     The seventh embodiment is characterized by automatically performing the alternation between the satellite communication and the cellular system. 
     It is now assumed that the vehicle M moves from a cell C 1  to a position A in another cell C 2  in the cellular mode, as shown in FIG.  21 . When it is wanted for the terminal equipment mounted in the vehicle M to continue the cellular communication, various controls including the switching of radio frequency depending on the movement of the vehicle M between the cells C 1  and C 2  and others must be carried out. This is called “hand-off” which is usually carried out in response to reduction of reception level or increase of error rate (see “EIA/TIA Project Number 2398”, 2,4,5 Mobile Assisted Hand Off). 
     It is now assumed that in the cellular mode, the vehicle M moves to a position B out of the cell C 1 , the position B being also out of the service area in the cellular system, as shown in FIG.  21 . Alternatively, it is assumed that when the first cellular system is being used, the vehicle M moves to the position B out of the cell C 1 , the position B being out of the service area in the first cellular system but within the service area of the second cellular system. In this case, the terminal equipment mounted in the vehicle M can continue the cellular communication only when it is shifted from the cellular system to the satellite communication system or from the first to the second cellular system. When the shift between different systems which are carried out by different service operators is performed without disconnection of the communication, it is called “alternating”. 
     The controller  16  monitors the operation of a reception circuit from the amplifier  13  to the modulator/demodulator  15  in the cellular mode and detects a signal reception level. The controller  16  simultaneously receives signals from a plurality of base stations BS 2  and compares these signals with one another. Thus, the controller  16  judges whether or not the maximum reception level throughout the base stations BS 2  exceeds a predetermined level. If the maximum reception level is higher than the predetermined level, the controller  16  sends a control signal to the base station BS 2  having the maximum reception level so that the cellular communication is continued via the base station (“hand-off”). If not so, the controller  16  judges that any communication with a signal quality better than the predetermined level cannot be carried out even by the use of the cellular system and informs the controller  9  of the reception level through the connectors  29  and  28 . The controller  9  monitors the operations of the components of the transceiver  5 C even in the cellular mode to detect the reception level or error rate. The controller  9  compares the reception level provided by the controller  16  with the reception level or error rate detected by the controller  9  itself. If the controller  9  judges that a better communication can be carried out by utilizing the satellite mode than by utilizing the cellular mode, it is reported to the controller  16  through the connectors  26  and  27 . Thus, the controller  16  actuates the switches  26  and  27  to select the satellite mode. This realizes the alternating from the cellular system to the satellite communication system. If it is not judged that good communication can be carried out in the satellite mode, the cellular mode will be continued. 
     In such a manner, the seventh embodiment can automatically select and perform the hand-off in the cellular communication or the alternating between the satellite communication and the cellular communication. The usability of the terminal equipment can be improved. 
     (8) Eighth Embodiment 
       FIGS. 22-24  show the eighth embodiment of the present invention in which a hand set  24 E is used in place of the hand set  24 D of the seventh embodiment. The hand set  24 E utilizes a base band circuit  7 A and voice codec  8 A in place of the modulator/demodulator  15 . The controller  16  performs the hand-off in the cellular system and the alternating between a plurality of cellular systems by detecting and comparing the signal reception level or the error rate (number of error bits per unit amount of information). The controller  9  performs the alternating between the cellular system and the satellite communication by detecting the error rate in the transceiver  5 C and comparing it with the signal reception level or the error rate in the cellular reception circuit. Therefore, the eighth embodiment can be applied to the digital cellular communication system. The other components and advantages are similar to those of the seventh embodiment.