JP3530135B2 - Signal decoding free of use of second synchronization word in mobile communication system - Google Patents

Description

Detailed Description of the Invention

Related Patent Application This formal patent application is filed by Paul W. Dent and Krister Rait.
Claims priority to provisional patent application serial number 60 / 085.710 filed May 15, 1998 in the name of h.

BACKGROUND OF THE INVENTION The present invention relates generally to transmitting and receiving signals in mobile wireless communication systems. In particular, the present invention is
The present invention relates to signal decoding in a mobile radio communication system having a function of interrupting transmission from a base station.

In time division multiple access (TDMA) wireless communication systems, each transmitter in the system is assigned a time slot for transmitting a wireless signal. This time
During the slot, all other transmitters are quiet so that the intended receiver can clearly receive this radio signal. If the wireless communication system is a two-way mobile system, such as a cellular radiotelephone system, the wireless carrier frequency within the first frequency band may be multiple times for communicating from the base station to multiple mobile stations.
The radio carrier frequency within the second frequency band is divided into slots and divided into time slots for communicating from different mobile stations of the plurality of mobile stations to the base station.
A base station communicates with mobile stations within a certain area near the base station. Other neighboring base stations serve mobile stations in the neighboring area.

During the base station's time slot, the base station transmits control and timing information. This information is
For example, the identification number of the mobile station that is scheduled to receive the call on the general call channel, the synchronization channel (sychoronization or
sync channel) synchronization information and timing information. A mobile station in the system receives the sync channel and uses the information in the sync channel to synchronize the timing of the mobile station with the base station. Each time slot typically contains a known data pattern that is useful for decoding the symbols transmitted in each time slot, making it easier for mobile stations to estimate the phase and amplitude of the channel. become.

To improve the reception and decoding of symbols, not only the sync word at the beginning of the next time slot and at the end of the current time slot, but also at the beginning of the current time slot is Known to be used.
Due to fading or other interference in the channel, the current or first sync word may not be reliably received. By storing the received signal sample that includes the second sync word, the stored symbol sample can be decoded using the first and / or the second sync word. This approach is described in U.S. Patent No. 5,335,250, issued to Dent et al., August 2, 1994, and November 24, 1998.
U.S. Patent, No. 5,841,81 issued to Dent et al.
It is explained in issue 6. Since these two patents are commonly assigned to this application, the disclosure content of these patents is hereby incorporated by reference. Some mobile stations currently in use utilize the reception of a second sync word for optimal performance.

In some mobile radio systems, time
It has been proposed to interrupt or modify the transmission of information containing sync words when slots are not assigned. If no time slot is assigned, then no mobile station is currently using that time slot. This means that the phase, amplitude or direction of transmission by the base station may change in the current time slot and subsequent time slots, and without the invention,
It will degrade the quality of operation of existing mobile stations. However, in order to reduce interference to receivers in the surrounding area, it is desirable that the base station not transmit information in unassigned time slots. Not sending sync words and other information during unassigned time slots reduces or eliminates this co-channel interference and improves overall performance in wireless systems. Removal of the mobile station's ability to use the second sync word compromises the realization of this improvement.

In the case of a mobile station that utilizes the reception of the second sync word to improve communication, if the time slot assigned to the mobile station is followed by an unassigned time slot, Removing the sync word or changing characteristics such as timing, phase or direction in the transmission of unassigned time slots would cause problems. The mobile station may not be able to successfully decode the channel and may spend more time than necessary to look for the second sync word. Therefore, there is a need for a method and apparatus that allows the removal of some time slot transmissions by a base station without degrading the performance of the remaining time slots in a mobile wireless communication system.

Detailed Description of the Presently Preferred Embodiment Referring now to FIG. 1, FIG. 1 illustrates a wireless communication system 100 including at least one base station 102, 104 and at least one mobile station 103. . Wireless communication system 1
00 may be a two-way wireless communication system such as a cellular wireless telephone system, a personal communication system (PCS), a trunked wireless system, or the like. The wireless communication system 100 in the illustrated embodiment is a cellular wireless communication system operated in accordance with the provisional standard IS-136 issued by the Electronic Industries Association of America (TIA) / Electronic Industries Association of America (EIA).

The system 100 shown in FIG.
There are two base stations, 2 and base station 104. In general, all base stations are configured the same, so the base station 10
2, the configuration and operation of the base station will be described. Base station 10
2 and a plurality of base stations of the system including the base station 104 are connected to each other to form a communication network. This communication network is controlled by a mobile services switching center (MSC) 106. MS
The C 106 is connected to each of the base stations 102 and 104 by a land line, a telephone line or a wireless line. MS
The C 106 controls the operation of the entire communication network, connects to the public switched telephone network (PSTN), controls the inter-operation of the base stations, and performs wireless communication between two base stations and one mobile station in the system 100. To perform functions such as handover of

Base station 102 is an example of the construction and operation of a base station. The base station 102 includes a controller 110, a transmitter 112, a receiver 114, a memory 116, a clock 118.
And an antenna 120. The controller 110 is
It controls the overall operation of the base station 102. Each base station is connected to one or more mobile stations within a certain area near the base station and two or more mobile stations.
Directional wireless communication is performed. The area is divided into a plurality of sectors, and each sector has an antenna 120 or an antenna 120.
Serviced by some of the.

Transmitter 112 uses antenna 120 to send radio signals to mobile stations, such as mobile station 130 within a region surrounding base station 102. The transmitter 112 may include functions such as coding, interleaving and modulation. The receiver 114 receives the radio signal received by the antenna 120 from the digital signal used by the base station 102.
Convert to data. The receiver can filter, demodulate,
Features such as decryption can be included. Memory 116
Operates the controller 110, and the base station 102
Stores data and instructions for use by other circuits within.

Clock 118 provides a time base for operating base station 102. Generally, base stations,
Devices operating in system 100, including MSC 106 and mobile stations, need to be tightly synchronized. Clock 118 is used to receive the sync signal from MSC 106 and then provide the sync signal to a mobile station, such as mobile station 130.

Those skilled in the art will appreciate that the base stations 102, 104 may include other functions and circuits.
These functions include the initiation of mobile station calls and the management of handovers that switch communication with the mobile station from one base station to another.

Mobile station 130 is an example of a mobile station capable of operating within system 100. The mobile station may be any radio capable of performing two-way wireless communication with a remote base station, such as a cellular phone, a PCS phone or other two-way radio. In the illustrated embodiment, the mobile station 130 is IS-
It is a cellular telephone that can operate in 136 ways. The mobile station 130 in the illustrated embodiment includes an antenna 132, a reception path 134, a transmission path 136, a controller 138,
It includes a memory 140, a user interface 142, a battery 144, a clock 146 and a synthesizer 148.

Receive path 134 receives the radio signal detected at antenna 132 and produces digital data for use by mobile station 130. Receive path 134 includes analog front end 150, demodulator 152 and decoder 154. Analog front end 150
Includes a low noise amplifier and a suitable filter for detecting and filtering the radio signal received at antenna 132. The analog front end 150, like a mixer connected to the synthesizer 148, shifts the frequency at which radio signals are broadcast to a low frequency, and the mobile station 1
Further included is circuitry to make processing within 30 more convenient. The demodulator 152 processes the received signal samples to determine an estimate of the channel propagated through the multipath by using the sync word or a known symbol pattern and then uses this channel estimate. And process the signal samples to produce soft-decisions with multipath and intersymbol interference compensation. When this soft decision is provided to demodulators 152 to 154, decoder 154 performs error correction coding to produce error correction information for controller 138.

The transmit path 136 converts the digital data generated by the controller 138 into a radio signal for transmission using the antenna 132. The transmission path 136 is
It includes an encoder 160, a modulator 162 and a transmitter 164. Encoder 160 encodes the digital data provided by controller 138 into the format required for communication in system 100, including interleaving. When the encoded data is provided to modulator 162, modulator 162 uses this data to modulate the carrier signal provided by synthesizer 148. The modulated carrier is provided to transmitter 164, which performs functions such as power amplification and filtering. The amplified carrier is
Applied to antenna 132 for transmission to remote base stations, such as base stations 102, 104.

Controller 138 controls the overall operation of mobile station 130. The controller 138 is preferably implemented as a microcontroller, a digital signal processor, a microprocessor, or a combination of these, and operates in response to data and instructions stored in the memory 140. User interface 1
42 includes a keypad, microphone, speaker and display to allow the user to control the mobile station. The battery 144 supplies power for operating the mobile station 130. Clock 146 provides timing for the circuitry of mobile station 130. In particular, clock 146 provides the timing signals used by controller 138 so that mobile station 130, including controller 138, can remain synchronized with other devices in system 100.

The wireless communication system 100 in the illustrated embodiment is a time division multiple access (TDMA) wireless communication system. That is, the system 100 allows each mobile transmitter in the system when active.
ers) are assigned time slots for transmitting radio signals. All other mobile transmitters in the same cell using the same frequency do not transmit radio signals during this time slot so that the intended receiver can clearly receive radio signals on that channel. . Of course, for other cells or different frequencies, other mobile stations can independently use the same time slot.

An example of a TDMA wireless communication system is a cellular telephone system according to the interim standard IS-136.
IS-136 defines a communication frame with 6 time slots, but these channels are usually assigned in pairs to form a full rate channel. Therefore, a full-rate channel is actually a 3-slot T
It is a DMA system. The combination of slots on the uplink frequency and slots on the downlink frequency creates a full-duplex channel for two-way communication between a base station and a particular mobile station.

FIG. 2 shows a communication format in the wireless communication system of FIG. FIG. 2 shows a portion of a communication frame 200 that includes three time slots, a first time slot 202, a second time slot 204 and a third time slot 206. Time slot 20
2, 204, 206 are all transmitted by the base stations within system 100 of FIG.

Each time slot contains a sync word. Thus, the first time slot includes sync word 212, the second time slot includes sync word 214, and the third time slot includes sync word 216. The sync word includes a predetermined data pattern at a predetermined position near the beginning of each time slot. This sync word is used by the receiving mobile station to synchronize the timing and decode the transmitted time slots.

The transmitting base station intends that each time slot and its associated sync word be received by one mobile station near the base station. But,
In the current IS-136 system, the intended mobile station is
All three time slots are transmitted at all times so that other time slots, such as subsequent time slots that are equal to or better than the intended time slot, can be received. The transmission format of IS-136 is such that the mobile station forwards information from the first sync word, or the second
It is symmetrical even if the time direction is reversed so that the information from the sync word can be modulated backwards. However, in future systems, time slots may be omitted when there is no data to send, reducing interference to unscheduled receivers but not giving the intended receiver a second sync word.

It is known to use the sync words of the current time slot and subsequent time slots to improve the reception and decoding of symbols by the mobile station. This technique is described in U.S. Pat.No. 5,335,250 issued August 2, 1994 to Dent et al. And U.S. Pat.No. 5,841,816 issued Nov. 24, 1998 to Dent et al. It is explained in. Since these two patents are commonly assigned to this application, the disclosure content of these patents is hereby incorporated by reference. The decoding technique of these references incorporated or any other suitable decoding technique is referred to as the first decoding algorithm or first decoding technique. As with the disclosed embodiment, the mobile station uses a second decoding algorithm, or second decoding technique, in situations where the base station cannot guarantee to send a sync word in a subsequent time slot.

According to the decoding and demodulation techniques described in these incorporated references, the mobile station receives an allocated time slot of TDMA frame time. Using the first decoding algorithm, the mobile station utilizes a known symbol called the first sync word that is transmitted near the beginning of the assigned time slot and near the beginning of the subsequent time slot. The received signal is transmitted using a known symbol, which is transmitted in the present invention and is referred to herein as a second sync word. In other words, the base station transmits the predetermined first data symbol and the unknown data symbol. The sync word or other known data pattern forms a predetermined first data symbol. The special data intended for a particular mobile station is the unknown data symbol. This unknown data symbol may be encoded call data, control data or other data. The base station in some systems transmits a predetermined second data symbol, such as the second sync word in the subsequent time slot.

In some systems it is not guaranteed that a known symbol at the beginning of a subsequent time slot, eg the second sync word, will be transmitted by the base station. This may be done, for example, to reduce co-channel interference to receivers in the surrounding area. If the base station's mobile station is not assigned a subsequent time slot, the base station may suspend transmission, including sync words, during the unassigned time slot to reduce co-channel interference. it can. Also, a base station may be a specific one of the areas covered by the base station.
Directional antennas may be used that allow time slots to be broadcast to the sector. This sector may be different from the sector in which the mobile station assigned to the current time slot is located. Therefore, if the beam direction changes, the second time slot may not be received following the data in the previous slot.

Due to these possibilities, the base station cannot guarantee the transmission of certain second data symbols, such as sync words, in subsequent time slots. Furthermore, even if the transmission of a given second data symbol is performed, it may not be available if the timing, phase or amplitude of the subsequent time slot is changed at the base station for some reason.
Since the mobile station uses the sync word to synchronize the timing and reception of the mobile station to the base station, any changes to these parameters will cause them to be out of sync and require resynchronization of the mobile and base stations. become.

If the base station is not guaranteed to transmit a known symbol at the beginning of a subsequent time slot, such as a sync word, or the timing, phase, amplitude or direction for transmission in the current time slot. If the continuity is not guaranteed, the base station signals the mobile station according to the present invention, indicating that the second sync word is unavailable. In other words, the base station sends an indication if the transmission of the predetermined second data symbol is not guaranteed.

The mobile station uses at least a predetermined first data symbol to decode the transmission from the base station. The signal transmitted from the base station has a predetermined second data symbol or second
Upon indicating that the sync word is reliable, the mobile station receives from the base station using the predetermined first data symbol, the predetermined second data symbol, or both, according to the “first” algorithm of the incorporated reference. Decode the time slot you made. Any suitable algorithm described in the incorporated references or other references may be used.

When the mobile station receives an indication that the predetermined second data symbol or second sync word is unavailable, the mobile station receives the second decoding algorithm at the selected time slot. The decoded signal. Second
The decoding algorithm only needs the known symbols transmitted in the selected time slot. This second decoding algorithm is exercised by permanently setting the quality of the second sync word to the lowest quality value, while maintaining an indication that the second sync word is unavailable.
It may be any variation described in the references incorporated above. In addition, any other suitable decoding algorithm that utilizes only one guaranteed sync word may be used.

Thus, the mobile station decodes the unknown data symbol using the predetermined first data symbol when this indication is transmitted, and the predetermined first data symbol and the predetermined data symbol when this indication is not transmitted. The second data symbol of is used to decode the unknown data symbol. This indication may be any suitable data or signal contained in the control signal information sent by the base station to the mobile station. This indication in one embodiment is sent during call setup or handover. Call setup occurs when two-way communication between a mobile station and a base station is initiated. Call initiation is when the mobile station indicates that the user wants to make a call,
Alternatively, it occurs when the base station sends an incoming call signal to the mobile station on the paging channel. Handover occurs when a mobile station moves from a service area of a first base station to a service area of a second base station. These two
Substantial control information is exchanged between the mobile station and the base station during the occurrence of one event.

The base station in one embodiment broadcasts the indication to all mobile stations within its service area or sector of its service area. This broadcast is accomplished using a Digital Control Channel or Broadcast Control Channel (BCCH) known as DCC. This display is
Notify the mobile station that the base station is using an operation mode that does not guarantee that the second synchronization word can be used. In response, all mobile stations in this sector or coverage area use the second decoding algorithm.

In another embodiment, the mobile station sends to the base station an indicator that the mobile station is requesting the second sync word to optimally decode the time slot information from the base station. Sending an indicator to the base station is well suited to mobile stations having this requirement. According to this embodiment, the mobile station transmits an indicator indicating that it is requesting the transmission of a predetermined second data symbol. In response to this indicator, the base station according to the present invention responds to this indicator with a predetermined second even if no data is transmitted in the next slot.
Reliably transmit data symbols. The base station not only interrupts the transmission of the second sync word, but also does not change the phase, amplitude or some other required characteristic of the transmission, but if it does not need to transmit the data, the transmission of the data following the second word Is omitted.

The indicator may include a predetermined data pattern or an indicator of the operating mode of the mobile station. The indicator may be sent together with the control information sent from the mobile station to the base station.

Further, the standard information transmitted by the mobile station to the base station may include an indicator. For example, each mobile station has a protocol version number that is sent to the base station when communication between the mobile station and the base station begins.
The protocol version number is the version of the standard used by mobile stations, such as IS-136. The base station is responsive to the protocol version number or some other similar indicator to determine whether the mobile station is waiting for the second sync word or is able to operate without sending the second sync word. decide. Further, one of these two modes of operation may be set to the default, using non-default conditions that are only selected when the base station makes the appropriate decisions. The base station in yet another embodiment operates in any mode by using an identifier, such as the mobile station's electronic serial number (ESN), that the mobile station transmits during call setup. You can judge. By comparing the mobile station's ESN with a value stored in memory at the base station or elsewhere in the network, the base station can determine which operating mode it should provide to the mobile station. The characteristics can be retrieved from the subscriber database. Therefore, the base station determines the transmission requirement of the mobile station and transmits the predetermined second data symbol in response to the transmission requirement of the mobile station.

FIG. 3 is a flow chart illustrating a method of operating a mobile station in the wireless communication system 100 of FIG. The method begins at step 302. Step 304
Then, the base station determines whether the mobile station (MS) is requesting the second synchronization word. This determination may be by way of receiving signaling information from the mobile station including an implicit indicator that the mobile station is requesting the second sync word, or by receiving an identifier or other information from the mobile station, Performed according to any suitable method, such as by comparing the identifier with the stored data and determining the transmission requirements of the mobile station. In the embodiment shown in FIG. 1, the controller 110 of the base station 102 forms the means for determining the type of a particular mobile station in wireless communication with the base station. Thus, the controller 110 may work with the memory 116 or with other data processing devices in the system, such as the MSC 106.

If the base station determines that the mobile station is requesting the second sync word, then in step 306 the base station transmits a first time slot containing the first sync word. Step 3
At 08, the base station transmits at least a second synchronization word.
Thus, two of the predetermined first data symbol (first sync word) and the predetermined second data symbol (second sync word) are unknown data in the first time slot transmitted by the base station. Provided to the mobile station for accurate demodulation and decoding of symbols. The transmitter 112 in the embodiment of FIG.
Together with 0, forms a means for transmitting a radio signal to a particular mobile station in response to a particular mobile station type during the current time slot and at least some of the subsequent time slots. To do. The method ends at step 310.

If, in step 304, the base station determines that the mobile station does not request the second sync word, then step 312
Then, the base station transmits the first time slot and the first synchronization word. Referring to the embodiment of FIG. 1, the transmitter 112
Responds to a particular mobile station type alone or with controller 110, if the particular mobile station is the second type, and sends a radio signal to the particular mobile station during the current time slot. And form means for transmitting radio signals adapted to the type of mobile station. Then step 3
At 14, it is determined whether the second time slot (ie, the time slot immediately following the first time slot) has been assigned. The second time slot is assigned if the second mobile station and the base station using the second time slot of the same radio channel are in two-way radio communication. During the subsequent time slot, if the base station is not in contact with any mobile station or if the mobile station assigned to that time slot is located in a different direction, the second or subsequent time • Transmissions during slots are interrupted or modified. If the second time slot is assigned, then in step 316, the base station transmits the second time slot and the second sync word required by the mobile station to which the second time slot is assigned.

If, in step 314, the base station determines that the second time slot has not been assigned, then in step 318 the base station determines whether the wireless transmission needs to be modified. Such a need exists, for example, if mobile stations located in different sectors of the area served by the base station are assigned the second time slot. If there is no need to change, control is step 3
Proceeding to 16, the second time slot and the second sync word are transmitted. However, if you need to make changes, step 3
At 20, the base station makes the necessary changes in the transmission and, at step 322, transmits the next time slot. The method ends at step 310.

FIG. 4 is a flowchart showing a method of operating a mobile station of the first type in the wireless communication system of FIG. The first type mobile station requests or waits for the transmission of the second synchronization word by the base station. The method is step 40.
Starts with 2.

In step 404, the mobile station remains in the loop trying to find a control transmission from the base station (BS). If no suitable transmission is found, the mobile station continues to find one. The mobile station may attempt to initiate the call by initiating two-way wireless communication with the base station, or may attempt to handover the communication from the first base station to the second base station to be found. May be.

The receive path 134 in the situation of FIG. 1 forms the means for receiving and decoding the signal from the remote base station. Analog front end 150, demodulator 152
And the decoder 154 is adapted to perform these functions. The design and implementation of these circuits, including hardware and software, as well as alternative embodiments, are fully described in the incorporated references. The new indicator signal provided by the present invention indicates whether the base station transmission is of the first type or the second type. The first type of transmission is
It includes symbols such as sync words in subsequent time slots that the mobile station 130 uses to decode the base station's transmissions.
The second type of transmission of the base station certainly contains no second sync word. Decoder 154 cooperates with controller 138 to
Means are provided for decoding the communication signal received from the base station in the assigned time slot of the TDMA frame time in response to the indication. Decoder 154 and controller 138 are suitably implemented as any combination of hardware or software that performs these functions.

In one embodiment, when a base station is found, the mobile station, in step 406, determines to inform the base station that it needs the second sync word to operate at optimal performance. In other embodiments, step 406 is not specifically executed. Rather, depending on the operating mode of the mobile station,
The software and other routines that control the operation of the mobile station may perform the following steps.

If the mobile station does not need the second sync word,
The mobile station can send an indicator in step 408.
As explained above, the indicator may be data or other information contained in a signal such as a control signal. The control signal may be, for example, an electronic serial number (ESN) or mobile station identification number (MIN) uniquely associated with the mobile station. When the indicator indicates the type of mobile station to the base station, whether the base station requires the mobile station to send a predetermined second data symbol in a time slot subsequent to the allocated time slot. To decide. The indicator may also be a special class mark or protocol version number that is transmitted to and used by the base station to determine that the mobile station is requesting transmission of the second sync word. Good. Further, the mobile station may only send identification information, such as an identifier similar to the mobile station's electronic serial number, which identification information is then used by the base station to determine the transmission requirements of the mobile station.

In step 408, the mobile station receives the first time slot transmitted by the base station and at least the second sync word. In step 410, the mobile station utilizes this second sync word to demodulate the first time slot. More generally, the mobile station demodulates and decodes the first time slot using any other suitable technique or any of the decoding techniques described above in the incorporated references. To do. In step 412, the mobile station determines whether more time slots are arriving or the call has ended. If the call is ongoing, control returns to step 408. When the call ends, the method ends at step 416.

FIG. 5 is a flow chart showing a method of operating a second type mobile station in the wireless communication system of FIG. The second type of mobile station does not require the base station to send the second sync word. However, in one embodiment, if the second sync word is available, the second type mobile station also uses the second sync word to optimize its performance. The method begins at step 502. Step 504 proceeds similarly to step 404 described above with a mobile station of the first type. In step 506, the mobile station sends an indicator that the second synchronization word may be omitted.

If the mobile station does not need the second sync word,
At step 508, the second type mobile station may receive an indication from the base station regarding whether the second sync word is available. In step 510, the mobile station receives the first time slot including the second sync word. Step 51
At 2, the mobile station checks if its second sync word is available, i.e. useful. If so, the mobile station proceeds to step 514 and uses the first demodulation algorithm using the first and / or second sync words. If not, the mobile station proceeds to step 516 and uses the second algorithm to demodulate the first time slot using only the first sync word. Next Step 51
At 8, the soft from the first consecutive time slot indicating whether demodulated using the first algorithm of step 514 or the second algorithm of step 516.
The decision is deinterleaved and decoded.

If the call should continue at step 520, control returns to step 510 to receive the next first time slot. If an optional slot-by-slot indication of the availability of the second sync word is provided, control returns to step 508. Otherwise, the method ends at step 522 when the call ends.

The illustrated embodiment provides a method and apparatus for accepting the elimination or modification of the transmission of certain sync words by a base station in a mobile wireless communication system,
It can be understood from the above explanation. Since the base station interrupts or modifies the transmission of subsequent sync words, it conveys to the mobile stations within its coverage area an indication that subsequent sync words are not certain. The mobile station in another embodiment may send an indicator to the base station that the mobile station is requesting the second synchronization word, in which case the base station may use the second synchronization for use by the mobile station. Keep sending words.

These embodiments allow for the deployment of improved base stations using state-of-the-art directional array antennas that adapt to the intended receiver location and can transmit different slots of different TDMA frame times in different directions. To Also, these embodiments enable the use of adaptive power control that can raise or lower the transmit power level of a time slot depending on the distance to the intended receiver. These two variants affect the properties of the second sync word. Using the illustrated embodiment, such an evolved base station would be able to maintain compatibility with the receiver of the mobile station utilizing the second sync word as before with respect to the previous time slot. It can be adapted to also allow the transmission of a second synchronization word in which the signal is continuous.

While we have shown and described specific embodiments of the present invention, modifications are possible. For example, the synchronization word transmitted in each time slot has been shown for use by a mobile station that demodulates and decodes the transmission from the base station. Can also be used by the mobile station. It is therefore contemplated in the appended claims to cover all such changes and modifications that come within the true spirit and scope of the invention. [Brief description of drawings]

FIG. 1 is a block diagram of a wireless communication system.

FIG. 2 is a diagram showing a method of operating a mobile station in the wireless communication system of FIG.

3 is a flowchart illustrating a method of operating a mobile station in the wireless communication system of FIG.

4 is a flow chart illustrating a method of operating a first type mobile station in the wireless communication system of FIG.

5 is a flow chart illustrating a method of operating a second type mobile station in the wireless communication system of FIG.

Continuation of the front page (56) Reference JP-A-5-30006 (JP, A) JP-A-6-97928 (JP, A) JP-A-5-268150 (JP, A) US Patent 5335250 (US, A) US Patent 5841816 (US, A) (58) Fields investigated (Int.Cl. ⁷ , DB name) H04J 3/06 H04B 7/26 H04J 3/00 H04L 7/08 JISST file (JOIS) WPI (DIALOG)

Claims (24)

(57) [Claims] 1. At least one base station and at least one
A method of operating a wireless communication system including two mobile stations, comprising: transmitting a predetermined first data symbol and an unknown data symbol at a base station; and selecting a predetermined second data symbol at the base station. Transmitting, in the base station, if the transmission of the predetermined second data symbol is not guaranteed, in the mobile station, using at least the predetermined first data symbol, Decoding a transmission from the base station. 2. The method of claim 1, wherein decoding the transmission includes decoding the unknown data symbol using only the predetermined first data symbol if the indication is transmitted. Decoding the unknown data symbol using the predetermined first data symbol and the predetermined second data symbol if the indication has not been transmitted. 3. The method of claim 1, wherein the predetermined first data symbol comprises a sync word for a current time slot. 4. The method of claim 1, wherein the predetermined second data symbol comprises a sync word for a subsequent time slot. 5. The method of claim 1, wherein the indication is transmitted at a base station if the base station interrupts transmission of a sync word during a subsequent time slot. 6. The method of claim 1, wherein the transmission of the indication is of the predetermined second data symbol having any of a certain timing, a certain phase, a certain amplitude and a certain directional continuity. A method of transmitting the indication if the base station cannot guarantee the transmission. 7. The method of claim 1, wherein an indicator at a mobile station is transmitted, the indicator indicating that the mobile station is waiting to transmit the predetermined second data symbol. And, at a base station, reliably transmitting the predetermined second data symbol in response to the indicator. 8. The method of claim 7, wherein the indicator comprises a predetermined data pattern. 9. The method of claim 7, wherein the indicator comprises an operating mode indicator for the mobile station. 10. The method according to claim 7, wherein the indicator includes an identifier of the mobile station, and in the base station, determining a transmission request condition to the mobile station in response to the identifier. Transmitting the predetermined second data symbol in response to the transmission request condition to the mobile station. 11. The method of claim 10, wherein the transmission requirements are retrieved from a subscriber database. 12. A mobile station operable in a wireless communication system and configured to receive transmissions of a first type and a second type from a remote base station, the mobile station receiving signals from the remote base station. And a means for decoding, wherein the signal indicates that the transmission of the base station is of a first type or a second type; and in response to the signal, the display is If the base station indicates that it is transmitting a first type, the symbols transmitted from the base station in subsequent time slots are utilized to allocate time division multiple access (TDMA) frame times. Unassigned after decoding the communication signal received from the base station in the assigned time slot and the indication indicates that the base station is transmitting a second type Of without using the symbols that are transmitted in the time slot, the mobile station and means for decoding the communication signal of the time slot. 13. A mobile station operable in a wireless communication system and configured to receive a first type and a second type of transmission from a remote base station, the mobile station comprising:
Wherein the transmission is a receiver configured to receive the transmission and generate data in response to data in the mobile station, the mobile station being composed of a plurality of consecutive time slots, Includes an indication, the indication having a first value if the transmission is of the first type and a second value if the transmission is of the second type A circuit connected to the receiver, the circuit configured to decode the data using data from a current time slot when the indication has the first value, A circuit configured to decode the data using data from the current time slot and a subsequent time slot if the indication has the second value. 14. The mobile station of claim 13, comprising a transmitter for transmitting a signal to the remote base station and a circuit configured to format data for transmission to the remote base station. And the data includes the circuit including an indicator that indicates to the base station whether the mobile station accepts the first type of transmission. 15. A mobile station operable in a wireless communication system including one or more base stations transmitting during a series of time slots, the transmission from said one or more base stations comprising:
A decoder configured to identify an indication of whether a subsequent time slot is available for reception, and during the current time slot a first number according to said indication.
A demodulator for demodulating a transmission from the one or more base stations according to any one of the first algorithm and the second algorithm. 16. The mobile station of claim 15, wherein the decoder is configured to identify the indication in data received from the one or more base stations. 17. The mobile station of claim 16, wherein the decoder is configured to provide the one or more of the ones during initiation of two-way communication between the mobile station and the one or more base stations. A mobile station configured to identify said indication in the data received from said base station. 18. The mobile station of claim 15, wherein the decoder is configured to identify the indication in the subsequent time slot. 19. The mobile station of claim 18, wherein the decoder measures a characteristic of a signal of the transmission from the one or more base stations during the subsequent time slot and the signal. A mobile station that is configured to identify the indication by comparing a characteristic of the. 20. A base station configured to operate in a wireless communication system, the base station signaling to one or more mobile stations within a predetermined geographical area, the mobile station. A base station which is one of a first type and a second type, means for determining a type of a specific mobile station in wireless communication with the base station, and the type of the specific mobile station. And (a) if the particular mobile station is of the first type, the radio for the particular mobile station during the current time slot and at least a portion of subsequent time slots. A signal, and (b) a radio signal for the particular mobile station in the current time slot and, if the particular mobile station is of the second type, a radio signal compatible with another mobile station type. Base station including, said means for transmitting. 21. The base station of claim 20, wherein the means for determining includes a circuit configured to determine the type of the particular mobile station based on a transmission from the mobile station. Station. 22. The base station according to claim 20, wherein the means for transmitting changes the transmission power level in the subsequent time slot, changes a phase of transmission in the subsequent time slot, and transmits in the subsequent time slot. A base station that adapts the wireless signal according to one of: changing the timing of the wireless signal, changing the transmission direction in the subsequent time slot, changing the modulation of the transmission, and changing the burst format in the subsequent time slot. 23. A time division multiple access (TDMA) wireless communication system, wherein at least one base station transmits a wireless signal during a series of time slots including a current time slot and a subsequent time slot. Wherein the radio signal is the base station including an indication of whether or not the transmission of the subsequent time slot is guaranteed, and the at least one mobile station receiving the radio signal according to the indication. , The display is the subsequent time
A mobile station including a circuit for decoding the radio signal using the information in the current time slot and the information in the subsequent time slot, when indicating that the transmission of the slot is guaranteed; The TDMA wireless communication system including: 24. A time division multiple access (TDMA) wireless communication system, at least one base station transmitting a wireless signal during a series of time slots including a current time slot and a subsequent time slot. Wherein the radio signal is the base station including an indication of whether or not the transmission of the subsequent time slot is guaranteed, and the at least one mobile station receiving the radio signal according to the indication. The mobile station is one of a type that requires guaranteed transmission of the subsequent time slot and a type that does not require guaranteed transmission of the subsequent time slot. And the at least one base station includes a circuit for receiving a signal from the at least one mobile station indicating a type of the mobile station. The TDMA radio communication system.