JP2000511750A - Method and apparatus for allocating spectrum resources in a wireless communication system - Google Patents

Abstract

SUMMARY The present invention contemplates a method and apparatus for efficiently communicating complex resource allocations from a central access point or base unit 14 to a mobile unit 10 requesting service. Base unit 14 distributes this resource among several competing mobile units 10-12 performing various applications. Therefore, it is often desirable to create a complex schedule to achieve the optimal assignment to provide the highest quality service to mobile units 10-12. By communicating the complex schedule of the uplink resources in one downlink transfer, the mobile unit 10 is free to transmit its data on the uplink without receiving the downlink simultaneously, reducing complexity. Significantly reduced.

Description

DETAILED DESCRIPTION OF THE INVENTION     Save spectrum resources in wireless communication systems                   Method and apparatus for distributing                                 Technical field   The present invention relates generally to communication systems, and more particularly to wireless communication systems. Method and apparatus for allocating spectrum resources.                               Background of the Invention   The communication system communicates with the base unit (or network) via radio frequency channels. Mobile units (8-slot half-duplex terminals, etc.) ) Is known. One such communication system includes both There is a wireless telephone communication system. In two-way wireless telephone communication systems, mobile Units are roaming transceivers, which are located at boundaries called cells. Included within delimited areas. In the cell, all communications are fixed and wired Through a single base unit containing transceivers connected to the infrastructure Done. Many systems pair radio frequencies into channels and use frequency division Full-duplex communication using a technology called multiplexing (FDD: Frequency Division Duplexing) I do. The mobile unit transceiver uses one radio, called the uplink. Transmits all outgoing information to the base unit using wave numbers, All incoming information is received using the other radio frequency called. These nothing Distribute line resources to mobile units in the cell and handle all competing requests appropriately Is the responsibility of the base unit.   Many wireless telephone communication systems use Time Division Multiple Access (TDMA). A mobile unit multiplexing technique called Multiple Access) is further adopted. This In this case, resources on a particular radio channel are divided by time and active mobile Shared between knits. Typically, resources are of equal duration (about 600 microseconds) Are quantified into a constant burst. These bursts form a plurality of bursts (8) Grouped into a series of frames, and a series of bursts in successive frames We call it. Generally, for circuit switching applications such as voice, the base unit is Radio channel time slots on both the uplink and downlink for Distribute. Uplink and downlink frames are staggered in time Mobile units transmit and receive one burst simultaneously This greatly simplifies radio design by eliminating the need. Mobile units are 72,000 individual bursts are always Used continuously, it occupies a pair of time slots during a time period (3 minutes). Resource allocation This stage generally takes much less time (1 second) and involves approximately 5 discrete It just uses bursts.   For the sake of signaling convenience, several consecutive bursts in a time slot are converted to other structures. Can also be integrated. For example, pan-European digitization for Europe Mobile communication (GSM: Groupe Special Mobile) digital cellular system Group four continuous bursts on a time slot into one block. Can be This block is a unit of measure for which error correction coding is applied It is. Further, it is convenient to allocate resources based on this block boundary.   Packets to replace these FDD / TDMA wireless telephone communication systems -A data communication protocol has been defined. Resource allocation for packet data communication Is much smaller (250 bursts) than a traditional circuit-switched call, Always send unidirectional bursts only on the uplink or downlink No. Furthermore, the data recovery scheme uses one block (4 verses) called an acknowledgment. Short transmission on the reverse link (ie packets are sent on the downlink) To the uplink) to indicate which burst was incorrectly received. Need to do. Generally speaking, these packets occur at random intervals. Raw Multiple mobile units at the same time or other mobile units in parallel. A service may be requested while transmitting a packet. Under certain conditions, act Preempt the mobile unit that is transmitting to the It is desirable to assign to knits. For example, access time and data rate are Prioritize mobile units based on required quality of service Need to be replaced to guarantee the promised service .   Traditionally, reservation-based packet systems generally adapt to the described system The start and end frames and a specific time slot Resource allocation for a continuous set of bursts by specifying in the U. In fact, Nortel has agreed on the GSM in Tdoc GPRS SMGS99 / 96. General Packet Radio Service (GPRS) This scheme was proposed. In such systems, downlink positive All supplemental traffic, such as responses, must be sent between uplink packets. Must wait until the end of the uplink packet. negative In a loaded system, by occasionally sending a downlink acknowledgment, It can take twice or three times the time it takes to send a downlink packet. And a lot of time is wasted waiting for an acknowledgment to be sent.   A more versatile method for resource allocation is the user state flag (USF: Use r State Flag) to secure and respond to the downlink block A method for identifying the status of an uplink block. This method is based on the current GS M GPRS specification, GSM03. 64 and version 1. 1. 0 is the method proposed You. The USF offers a great deal of flexibility, and base units can use resources as needed. Allocation can be distributed and for acknowledgment while having the option of replacement Leave room for. However, this scheme has enormous costs. in this way , It is necessary for mobile units to constantly monitor downlink time slots . For a mobile unit operating in only one time slot, as described above, Frames are staggered in time, and mobile units receive bursts simultaneously This is not a significant burden, as there is no need to send. However Properly decodes USF if mobile unit requires some slots In some cases, transmission and reception must be performed at the same time. Such a mobile unit The unit has a duplexed filter that allows the mobile unit to receive and transmit at the same time. The unit must be provided, which greatly complicates the unit.   Therefore, the mobile unit does not need to simultaneously receive and transmit There is a need for a method and apparatus for communicating complex resource allocations to units.                           BRIEF DESCRIPTION OF THE FIGURES   FIG. 1 shows the system.   FIG. 2 shows the flow of a communication call between a mobile unit and a base.   FIG. 3 shows a typical TDMA frame structure.   FIG. 4 shows a typical offset between the TDMA uplink and downlink. Show.   FIG. 5 shows a basic uplink resource map of a half-duplex mobile unit.   FIG. 6 shows uplink resource allocation with active circuit users.   FIG. 7 shows the format of a representative resource allocation message for the resource allocation of FIG. Show   FIG. 8 illustrates an uplink with an active user when there is a circuit switching user. Resource allocation.   FIG. 9 shows the format of a representative resource allocation message for the resource allocation of FIG. Show   FIG. 10 shows the alternatives used to replace the user distribution shown in FIG. 4 shows the format of a tabular resource allocation message.   FIG. 11 shows an example of an account after replacement by another user using the message of FIG. Upline with active users Resource allocation.   FIG. 12 illustrates an uplink resource including a periodic gap with active circuit users. Indicates the source allocation.   FIG. 13 shows the format of a representative resource allocation message.   FIG. 14 is a flow chart of a method showing the resource allocation required by a mobile unit. You.   FIG. 15 shows a method of indicating a response from the network in response to the request of FIG. It is a flowchart.   FIG. 16 secures a gap for Terminal 2 in response to the request of FIG. 4 is a flow diagram of a method showing a response from a network to be sent.   FIG. 17 is another flow diagram of a method showing the resource allocation required by a mobile unit. It is.   FIG. 18 illustrates the mobile unit's access to the reverse link in response to the request of FIG. 5 is a flowchart of a method showing a response from a network to secure a gap for access. You.   FIG. 19 illustrates yet another method of indicating the resource allocation required by a mobile unit. It is a flowchart.   FIG. 20 illustrates the redistribution of the current mobile unit in response to the request of FIG. If you indicate a response from the network to send a new allocation message if It is a flow chart of a law.   FIG. 21 shows an update with an active user before replacement. Indicates the uplink resource allocation.                         Description of the preferred embodiment   Generally, the present invention provides services from a central access point or base unit. For efficiently communicating complex resource allocations to mobile units that require traffic And devices are contemplated. The base unit has several competing performing various applications Responsible for allocating these resources among the mobile units that do so. Therefore, the mobile unit In order to make the best allocation to provide the highest quality service to It is often desirable to create a schedule. Communicating this assignment Can be expensive in terms of the hardware requirements of the mobile unit. Communicate complex schedules of uplink resources in one downlink transfer The mobile unit is up without having to receive the downlink simultaneously. Freely send that data over the link, greatly reducing complexity Will do. This method requires that the mobile unit be full duplex, or In contrast to conventional techniques that require having an inflexible allocation scheme .   More specifically, allocate spectrum resources in a wireless communication system A method for doing so is disclosed. The method is implemented from a terminal of a wireless communication system. Vector resources Sending a request for spectrum resources and an allocation message for allocating spectrum resources. Receiving a reply having a message in the window. Of a plurality of non-consecutive blocks. Preferred practice In the example, the spectrum resources are built on radio frequency bandwidth and wireless Communication systems include cellular communication systems and wireless local loop communication systems. A time division multiple access communication system and a code division multiple access communication system, It is a digital communication system constructed with at least one communication system. Spec Requests for vector resources consist of packet channel requests, The message is composed of a packet resource allocation message.   The bit map distribution may be less than that provided for transmission by the second terminal. And at least one gap is provided with a link access At least one of channel, control information transfer and reverse link acknowledgment Corresponding to one. The at least one gap further establishes some of the spectral resources. To provide the terminal with access to the reverse link. To reverse link Access includes at least acknowledgment, transfer of control information and reassignment messages. Is also used for one.   In a preferred embodiment, the terminal is a half-duplex terminal or a unidirectional terminal. Minal and wireless communication system The system is a two-way communication system. Terminals (mobile units) in the system Sends request for spectrum resources from terminal of wireless communication system Means for allocating spectral resources and a plurality of discrete blocks in the window for allocating spectral resources. Lock reply with allocation message composed by bitmap allocation Receiving means.   A communication system for allocating resources is also disclosed. The communication system is a mobile unit A message containing information about the multi-slot capabilities of the and the desired resources The mobile unit receives the message sent from the mobile unit and Move message containing resources, start time information and block allocation bitmap And a base unit for transmitting to the knit. In this embodiment, the distribution The amount of resources divided is the number of mobile units transmitted from the mobile unit to the base station. It is based on information about the double slot function and the desired resources. Mobile unit The message sent from the server is a packet channel request (PACKET CHAN). NEL REQUEST) message, from the base unit. The message sent to the mobile unit is a packet fixed immediate assignment (PACKET  FIXED IMMEDIATE ASSIGNMENT) message. Are composed. The base unit sends a packet channel request to the mobile unit. Transmit the packet fixed immediate assignment message on the same channel as the   A method for allocating resources to mobile units in a wireless communication system is also disclosed. It is. A wireless communication system may include a frame and a predetermined number of time slots within the frame. And a predetermined frame structure including the The method retrieves information from the mobile unit. Receiving, based on the block allocation information and the information received from the mobile unit. How to transfer multiple blocks of resources to a mobile unit within a given frame structure Time slot availability information indicating whether to allocate, and the mobile unit And generating frame start information indicating when to start. You. The method comprises a block allocation information, a time slot availability information and a frame. Sending start information to the mobile unit so that the mobile unit utilizes the allocated resources And the step of making it possible.   In this embodiment, the mobile unit is a half-duplex mobile unit having a multi-slot function. The knits are further configured with multiple blocks of resources within a predetermined frame structure. Of time slots are used by other mobile units. It is variably distributed over the frames in the frame structure. Multiple blocks of resources , Whether periodic gaps in time slots in a given frame structure are required Variably distributed to frames within a predetermined frame structure. Predetermined Periodic gaps in time slots in the frame structure cause resources to be used by other mobile units. Message available for availability or half-duplex mobile unit Required to be able to make measurements. Block assignment information Information, time slot availability information and frame start information are stored in the mobile unit. Indicate how the receiver or transmitter uses the resource. In a corresponding way The mobile unit used is a transmitter / transmitter that transmits signals and receives signals from base units. It has a receiver means, and the block allocation information and time stamp generated by the above process. Provide resource allocation to mobile units from lot availability information and frame start information Further comprising a decoder.   Another method of allocating resources to mobile units in wireless communication systems has been developed. Is shown. The wireless communication system has a predetermined frame structure. Includes a frame and a plurality of time slots within the frame. This method is for mobile Mobile unit requests allocation of resources based on arrival of information addressed to the knit And the block allocation information and the information received from the mobile unit. How multiple blocks of resources are transferred to mobile units within a given frame structure Time slot availability information indicating whether to allocate to Generating frame start information that indicates when the application should start. This method Contains block allocation information, time slot availability information and frame start information. Sent to the mobile unit to make it available to the allocated resources. Further comprising the step of: In this embodiment, the method includes the base unit. Information that runs within the network and is destined for mobile units Emitted from an external source. In this case, the mobile unit also has the multi-slot function. Is a half-duplex mobile unit.   The allocation method disclosed herein according to the present invention provides a Td in Stuttgart oc SMG2 A new class of mobile unit first introduced in GPRS 183/97 The MAC layer is extended to cope with the above. By definition, this new class of mobile units The low complexity of transmitting or receiving all eight time slots. It features a half-duplex RF layer. This is a high-performance GPRS as a popular service Has the potential to enhance GSM's competitiveness in the global telecommunications market.   As described in Tdoc SMG2 GPRS 183/97, a new class of mobile units The half-duplex nature of MAC uses a MAC scheme that includes USF bits as currently defined. No need to use. Current USF schemes allocate bandwidth on the uplink. It provides an efficient and flexible means to separate. But this scheme moves Require unit to monitor downlink simultaneously while transmitting on uplink I do. The new class of high-performance mobile units only need to perform one or the other.   To accommodate this mobile unit, a set of new messages has been defined and detailed. Communicate the fine fixed uplink resource allocation to the mobile unit. The fixed allocation is Laem and Lot allocation (time slot / bitmap) and allocation for each time slot A block allocation bitmap representing a block to be allocated. Move to receive this distribution Unit is free to uplink without monitoring USF on downlink Can be sent on. In this way, a half-duplex mobile unit can have a relatively short bus. Packets can be transmitted within the frame, and the quality of frame transmission delay is high. Providing services. Furthermore, this allocation scheme has the same level as the USF bit method. Provides the flexibility to support different mobile unit classes simultaneously. Is shown.   The protocol defined herein complements the existing protocol. The mobility classes that can receive downlink time slots during transmission are indicated by The USF bit must be used as described. The extension of this protocol allows new For mobile units other than 8-slot half-duplex of the class, the MAC / RLC layer is revised. It is not strange. This extension will cover the network for this new class of mobile units. It only affects the scheduler within the network.   FIG. 1 shows the system. As shown in FIG. 1, a plurality of mobile units 1 0-12 communicate with the base unit 14. FIG. 2 shows the mobile unit 10 and the base unit. 1 shows a normal call flow to and from a knit 12. Resource request (RESOURCEREQ) In the UEST message 16, the mobile unit 10 determines its function (ie, Double slot half duplex) Communicate with resources. For a typical Internet Protocol packet , The size of the resource is typically 1500 octets, which is the standard GPRS coding In the scheme, it can be conveyed in 66 blocks. Base unit 14 , Upon receipt of this message 16, the other mobile units 11-12 in the system The resource allocation (RESOURCE ASSIG). NMENT) must be precisely communicated to the mobile unit 10 via the message 18 No. As mentioned above, in the half-duplex mobile unit 10, such an allocation Problem arises with   In a preferred embodiment, mobile units 10-12 and base unit 14 , The structure of the GSM digital cellular system, shown in FIG. Compatible with structure. As shown in FIG. 3, frame 30 is well known in the art. Is constructed with eight time slots 32-39. Also shown in FIG. 3 ( As also described above), block 40 comprises four blocks in four consecutive frames. Constructed in the same time slot, block 40 is adapted for error correction coding. Represents a unit of measure. Block 40 is also a convenient boundary for allocating resources . Uplink for mobile units with full duplex capability, as is well known in the art And downlink transmissions are typically offset by a variable amount as shown in FIG. It is.   Packet generation for 8-slot half-duplex mobile unit 10 The communication defines a fixed allocation and schedules during the access phase of packet transmission. Need to communicate by the network. Due to the fixed distribution, the mobile unit 10 Send blocks without simultaneously monitoring the USF bit on the uplink. Can be. Many competing uses of the uplink-downlink acknowledgment, no Variety of mobile unit classes, including random access requests, circuit traffic, etc. Fixed allocation is affected by available slots and blocks. I have no choice. In other words, the allocation includes the active units currently on the system. Includes gaps to compensate for slot mobile units, leaving room for acknowledgments Need to packetize traffic in the reverse direction (uplink). This section The action defines an efficient way of communicating detailed resource allocation to the MS.   Two new types of messages support fixed allocation schemes. That is, the present invention Fixed Immediate Allocation by PACKET FIXED IMMEDIATE ASSIGNMENT) message 52 and packet fixed resource allocation (PACKET)  FIXED RESOURCE ASSIGNMENT message 56 . These messages are typical one- and two-step actions as shown in FIG. PACKET IMMEDIATE ASSIGN MENT) message and packet resource allocation (PACKET RESOURCE A) SSIGNMENT) message. First Pake ・ In the channel request message 50, the mobile unit 10 (all other mobile Half-duplex mobile units such as Network. Upon receiving the request, the network places the mobile unit in 8 scans. Recognizes as a lot half-duplex MS and replaces normal packet immediate assignment message In response, it responds with a fixed packet immediate assignment. As with two-step access, network Sends the fixed packet resource allocation instead of the normal packet resource allocation message. Attached. In the first stage of the two-stage access, the network In the meantime, the 8-slot half-duplex mobile unit 10 It works as a simple class.   The fixed allocation message is proposed in Tdoc SMG2 GPRS 174/97. A set of fields that are approximately equal to the corresponding field. However, 24 If the USF value is an 88-bit block allocation bitmap (BLOCK ASS IGNMENT BITMAP), and according to the invention, in fixed allocation Identify the block to be used. In addition, an 11-bit frame number is added to The start block (START FRAME) of the first block in the map You. As will be appreciated by those skilled in the art, the block allocation bitmap and start frame are displayed. The number of bits used for this may vary depending on system requirements. Time Combined with inter-slot bitmap (TIMESLOT BITMAP) And start The frame and block allocation bitmap uniquely defines the allocation. block The allocation bitmap represents a window in which blocks can be allocated. start A frame defines the start of a window, and the number of time slots allocated Define the size of the window. For any number of time slots, a total of 88 Blocks can be allocated. Block allocation bitmap You can think of it as a. If eight time slots are allocated, the bitmap is Represents an 8x11 array block. The number of blocks allocated to each time slot is 8 It is represented for every th bit. Similarly, when four time slots are allocated , The bitmap represents a block of a 4 × 22 array, and if every fourth bit is the same, Represents a block from the inter-slot. With this encoding scheme, we go to GPRS It is possible to communicate resource allocations of similar size even if two time slots are allocated. Can be.   FIG. 6 shows a lightly loaded system with active users according to the present invention. 4 shows a possible uplink resource allocation in the system. In FIG. 6, each column is Represents the block allocation in a particular time slot, where each row is time from top to bottom Represents a new frame with increasing intervals. Blocks marked "Open" are assigned Indicates none. Packet Random Access Channel (PRACH) om Access CHannel) is a resource request message. Indicates that the message will be specified. The block marked “a” is assigned to user a. Assigned.   Referring to FIG. 6, one and half packets known to schedulers in the network The uplink resource allocation during multiple frames of a packet is shown. As above, each Rows indicate assignments or combinations for new frames, and columns indicate time slots. The activity of each unit is shown. The content of each cell represents the resource allocation that needs to be communicated. No. In FIG. 6, all time slots are packet data channels (PDCH). : Packet Data CHannel), and time slot 0 is A master packet data channel (MPDCH: Mas) including four PRACHs ter Packet Data CHannel). Also, one 8-slot half-duplex mobile unit A knit is scheduled and marked as mobile unit a. Network fixed packet The start frame is set as 1017 in the start frame portion of the immediate assignment message 52. By communicating this distribution by specifying. FIG. 7 shows a typical packet according to the present invention. A packet fixed immediate assignment message 52 is shown generally. As shown in FIG. The time slot bitmap (referred to as “time slot allocation” in FIG. 7) Is set to “1”, indicating that all time slots are active, and a message The appropriate bit in the block allocation bitmap portion of Sage 52 is set to "1" To represent the allocated blocks. In this example, FIG. FIG. 6 shows the determination of bit allocation in the GSM frame structure.   To illustrate the flexibility of the allocation message, consider a more complex example. FIG. Uplink resource with active user between and half packet multiplex frame Indicates the source allocation. In this example only, six time slots are allocated to the PDCH. Time Inter-slots 4 and 5 are used by circuit switching users. 6 for mobile units That only certain time slots have been allocated This is indicated by the time slot bitmap portion of page 52 (FIG. 9). this In this case, this is "11110011" and time slots 4 and 5 are half-duplex mobile users. It is not distributed to the knit (for example, the mobile unit 10). network Is the start frame in the start frame portion of the packet fixed Communication of the start frame to the mobile unit 10 by specifying the I do. As mentioned above, time slot 0 is the MPDCH and mobile unit a has 8 A slot half-duplex mobile unit (eg mobile unit 10). Also two , The mobile units 11, 12 (b, b in FIG. 8) c) is using the system. Finally, another mobile unit marked d The packet acknowledges the packet sent on the downlink. Figure 9 shows this A representative that the network transmits to the mobile unit a via the base unit 14 in the case Typical pa 5 shows a format of a packet fixed immediate assignment message 52. This includes a message A block allocation bitmap portion of page 52 is included. As illustrated in FIG. The six columns used represent the distribution for the six PDCH time slots. Move Stay in the gap at the start of time slots 2, 7 included to correspond to units b and c. I want to be reminded. Similarly, the gap in time slot 3 is provided by the mobile unit marked d. Acknowledgment transmitted. As you can see from this example, fixed block allocation The method is extremely flexible, does not cause collisions, and does not cause problems with the prior art Allows multiple mobile units to access the channel. <Mobile terminal packet transfer>   There are two possibilities for delivering a packet to an eight slot half-duplex mobile unit 10. is there. This class of mobile unit is an eight-slot full-duplex mobile With the current message set performing a transaction very similar to the transaction It is thought that we can cope. Alternatively, if the network The packet schedule is fixed in the same way as the uplink, and the mobile unit Other activities may be performed when not receiving.   The network has eight full slots for an eight slot half duplex mobile unit 10. Same as for dual mobile units A method can be used to deliver downlink messages. However, this includes The network knows that mobile unit 10 is transmitting on the uplink Be especially careful not to send blocks on the downlink if Needed. Tdoc SMG2 GPRS 174/97 supports TFI, assigned time slot RLC packet resource allocation (R LC-PACKET RESOURCE ASSIGNMENT FOR DOWN LINK) message. The 8-slot half-duplex mobile unit 10 is Monitor the downlink to detect the downlink block with the assigned TFI. Can be found. In addition, an 8-slot half-duplex mobile unit would require U The SF bit is used to identify the block sending the ACK on the uplink. Can be. Of course, if you send an ACK, you will receive a downlink block. I can't do that. Therefore, the network will be down during mobile unit transmission. It is necessary to postpone the sending of the link block. In addition, every time slot Only one contiguous block can be allocated. This is a mobile unit This is because the unit 10 does not read the second set of USF bits. All of these Considering this, the eight-slot half-duplex mobile unit 10 has Traditional message sets can be used as long as the following principles are adhered to:   1. The network uses USF for an 8-slot half-duplex MS. Using a bit scheme, two or more consecutive uplinks per time slot Never distribute blocks.   2. The network overlaps with the assigned uplink block of the same MS 8 Never send a downlink block containing information destined for a slot half-duplex MS I do not believe This restricted downlink block contains user data Both blocks and blocks containing USF bits for the MS are included. time The slots allow the allocated uplink blocks to be allocated to the downlink / uplink. The uplink frame offset and the uplink and downlink block The transmission of some downlink blocks as a result of the relative phase of the Sometimes.   3. 8-slot half-duplex MS decrypts USF allocated on downlink At any time, exactly one block on the uplink in the allotted time slot Must be sent.   With the allocation method described herein according to the present invention, these system requirements are: Unnecessarily burdensome. As an alternative, which downlink block has 8 slots Fixed to accurately specify whether it contains data destined for the half-duplex mobile unit 10 A resource allocation message is defined. This fixed resource allocation message has an associated Uplink acknowledgment distribution is also included. Of the transmitted downlink block Number More than one or two acknowledgments are required. Related downlink block The encoding of the start frame, time slot bitmap and block Unload bitmap (BLOCK ANNOUNCEMENT BITM) AP). These three fields are Link counterpart, but the block announcement bitmap Which downlink block in the window is an 8-slot half-duplex mobile unit 10 The difference is that it is specified to be addressed to. Start frame is block announcement Set the first frame in the segment bitmap and set the time slot bitmap Is the size of the window (ie, the time slots in the frame are allocated accordingly). Divided). In addition, allocated on the uplink for acknowledgments Each block has a 5-bit acknowledge frame offset (ACKNOWLEDG) EMENT FRAME OFFSET) with 3 bit time slot It is conveyed by specifying. The acknowledgment frame offset is Block that should be added in combination with the system to acknowledge the downlink packet. Decide the lock. This latter scheme mimics the uplink allocation method Thus, the convenience of the mobile unit 10 is achieved. <Inference on the current MAC / RLC layer>   For other mobile units in the system, the protocol No modification is needed. All other classes of mobile units have the currently defined U The protocol based on SF bits will continue to be adopted. Eight networks (or Or 7 USFs), and use them for 8 slots 1/2 Must mark uplink status during fixed allocation for heavy mobile units Must. Regardless of the planned number of 8-slot half-duplex mobile units, these Mobile units rely on fixed resource allocation messages only, so there is only one USF Only need to be secured. Similarly, other classes of mobile units have 8 slot half duplex There is no need to distinguish between allocation of mobile units and other mobile units.   Systems such as service quality, power control, timing advance and measurement reports The problem is mentioned in other papers. <Replacement and reassignment>   GPRS and many other systems offer services that are compensated for their subscribers. Interested in providing quality of service (QoS). QoS is approved Measured with respect to the average packet transfer delay experienced by the subscriber for different data rates It is. To guarantee QoS, GPRS assigns users different wire levels, The user has to send it each time he tries to access. Network Must recognize this priority and schedule users appropriately. No. High priority mobile units When a low-priority mobile unit sends a request for a service, the low-priority Units are replaced by higher priority mobile units. Described herein Fixed allocations are preferred because they cannot be monitored during the transmission of half-duplex mobile units. Appropriate scheduling of mobile units with high priorities can be prevented. Network Schedules continuous allocation for low-priority half-duplex mobile units And the mobile unit cannot receive the reassignment message, resulting in Cannot be replaced. FIGS. 21, 10 and 11 illustrate this problem. Here are some possible solutions.   FIG. 21 illustrates an uplink resource allocation with active users before replacement. Show. Due to critical gaps in the uplink distribution, the network may be re- An assignment message can be communicated to the mobile unit. During the gap, the moving unit A low priority mobile unit marked a stops transmission and monitors the downlink. To watch. If no reassignment message arrives, continue with the current assignment and wait for the next Resume transmission until the time. But the network does not send the reassignment message The mobile unit with a lower priority stops transmitting and reserves a new allocation period. At this time, the mobile unit with a higher priority, which is described as mobile unit b, is And send the packet. FIG. 10 shows a low priority mobile unit. a of the distribution of FIG. Indicates encoding. FIG. 11 shows that the low priority mobile unit a in FIG. Figure 3 shows the distribution of results after being replaced. <Periodic gap>   The scheduler in the network has a complete view of downlink traffic Often not. Uplink to accommodate other mobile units in the system It is difficult to accurately schedule gaps in allocation messages. Therefore, Uncertain downlinks in the future with periodic gaps in the distribution of mobile units It is advantageous to be prepared for traffic. FIG. 12 shows the active circuit user FIG. 13 shows the uplink resource allocation including the accompanying periodic gaps, FIG. Of a representative resource allocation message to generate the required uplink resource allocation. Indicates a mat. As shown in FIG. 12, the network has a variable time slot. Schedule approximately one gap per frame in a slot for convenient download Link acknowledgments can be conveyed on the uplink as needed. In addition, alternating time slots are available for other classes of mobile units using the system. For maximum convenience. For example, a single slot mobile unit (one TDMA time slot) Mobile units that operate only in lots) have downlinks that terminate packet forwarding Before sending an acknowledgment, it is sufficient to wait up to eight blocks. Similarly, Multi-slot mobile units are instantly dumped due to gaps in all frames. Link acknowledgment can be sent. Schedule periodic gaps Network will ultimately reduce system latency and reduce The unit will provide higher quality service.   FIG. 14 is a diagram of a mobile unit 10 having a half-duplex multiplex slot function. 1 generally illustrates a flow diagram of a method for indicating resource allocation. The process starts at step 1400 Beginning, proceed to step 1402, where the packet to be sent by the mobile unit 10 Wait for. Next, the mobile unit 10 passes the packet on the access channel in step 1404. The allocation request is transmitted via the channel request message 50. Step 1406 The mobile unit 10 sends a packet fixed immediate assignment message 52 on the downlink. Receive the distribution message in the form of Mobile unit 10 receives a message at step 1406. Based on the contents of page 52, the distribution for the transmission time is determined, and the process proceeds to step 1. Proceed to 410 where the block is allocated by the mobile unit 10 for transmission. A test is performed to determine whether the test has been performed. If the test result is yes, Flow proceeds to step 1412, where a segment of information is sent between mobile units 1 Sent by 0. However, if the result of the test at block 1410 is no, If not, step 1412 is skipped and flow proceeds to step 1414, where the distribution window A test is performed to determine whether the dough is complete. Step 1414 test If the result is yes, flow proceeds to step 1402 and the process is repeated. However, if the test result is also no at step 1414, the next of the information to be transmitted is The segment is collected at step 1416 and the flow proceeds to step 1410 where it is tested. Is repeated.   FIG. 15 illustrates a base unit in a network that responds to the request shown in FIG. 1 generally illustrates a flow diagram of a method for indicating a response from a unit 14. Start at stage 1500 , The flow proceeds to step 1502, where the network establishes a need for distribution by mobile unit 10. Wait for a request. In step 1504, the network associates with mobile unit 10. Determine the allocation window to perform, and proceed to step 1506, where other types of traffic Perform a test to determine if a block is needed for the information. Stage 15 If the test result of step 06 is yes, flow proceeds to step 1508 where the network is The network inserts gaps in the distribution to accommodate other types of traffic information. However If the test result of step 1506 is no, step 1508 is skipped and the flow is Proceeding to floor 1510, the network sends an allocation schedule to the mobile unit . Upon completion of step 1510, flow proceeds to step 1502, as shown in FIG. The whole process is repeated.   FIG. 16 shows a response for securing a gap for the second mobile unit, and FIG. In response to the request shown in the diagram, 1 generally illustrates a flow diagram of a method for indicating a response emanating from a network. Process is a stage Beginning at 1600, proceed to step 1602, where the network establishes a mobile unit Wait for a distribution request from 10. If a request is received, the network proceeds to step 16 At 04, the distribution window of the mobile unit 10 is determined and proceed to step 1606. A test is performed to determine if another second terminal wants to transmit You. If the test result in step 1606 is yes, flow proceeds to step 1608, where the net is The network inserts a gap in the distribution to another specific communication channel of Terminal 2 Access to If the test result of step 1606 is no, step 1608 Is omitted and flow proceeds to step 1610 where the network schedules the distribution Transmit to mobile unit 10. At step 1610, flow proceeds to step 1602. And the whole process is repeated.   FIG. 17 is a flowchart of a method showing the resource allocation required by the mobile unit 10. Is generally shown. Referring to FIG. 17, the process begins at step 1700, where steps Proceed to 1702. Here, the mobile unit is connected to the base unit 14 in the network. Wait for a packet of information to send. In step 1704, the mobile unit The packet 10 is transmitted via a packet channel request message 50 on the access channel. And sends a distribution request. In step 1706, mobile unit 10 is down. Distribution messages on the link (for example, The packet fixed immediate assignment message 52) is received. In step 1708, move Unit 10 determines the distribution for a particular transmission time. The mobile unit 10 At step 1710, it is determined whether the block has been allocated for transmission. Perform a test for If the test result in step 1710 is yes, the flow is step 17 Proceeding to 12, a segment of information is transmitted during the allocated block. Stage 1 If the test result at 710 is no, the mobile unit 10 A message is received from the ground unit 14 on the downlink. Steps 1712 and Following the steps 1714 and 1714 is step 1716, which determines whether the allocation window has been completed. A test is performed to determine If the test result in step 1716 is yes, Goes to step 1702 and the entire process is repeated. However, in step 1716 If the test result is no, flow proceeds to step 1718, where the next transmitted segment Are collected. Following step 1718, flow proceeds to the test at step 1710 , The lower half of the flow shown in FIG. 17 is repeated.   FIG. 18 illustrates the access of a mobile unit to the reverse link according to the invention. FIG. 17 shows a response from the network in response to the request of FIG. 1 schematically shows a flow chart of the method. As shown in FIG. 18, the flow proceeds to step 1800 And proceeds to step 1802 where the network allocates from mobile unit 10 Wait for a request. The flow is a step Proceeding to floor 1804, the network determines the distribution window from mobile unit 10. Set. In step 1806, the mobile unit 10 accesses the reverse link. A test is performed to determine if a block is needed for the service. Step If the test result for floor 1806 is yes, the network inserts a gap in the distribution , The mobile unit 10 can access the reverse link at any time. Only However, if the test result of step 1806 is no, step 1808 is omitted and the flow is Proceeding to floor 1810, the network sends an allocation schedule to mobile unit 10. I believe. After step 1810, flow proceeds to step 1802, shown in FIG. The whole flow is repeated.   FIG. 19 is a flowchart of a method showing the resource allocation required by the mobile unit 10. Is generally shown. Referring to FIG. 19, the process begins at step 1900, where steps Proceed to 1902. Here, the mobile unit is connected to the base unit 14 in the network. Wait for a packet of information to send. In step 1904, the mobile unit The packet 10 is transmitted via a packet channel request message 50 on the access channel. And sends a distribution request. In step 1906, mobile unit 10 is down. Distribution message on link (eg, packet fixed immediate allocation message 52) To receive. In step 1908, mobile unit 10 associates a particular transmission time. To determine the distribution. The mobile unit 10 moves to step 1910 Test to determine if the block has been allocated for transmission at Run. If the test result in step 1910 is yes, flow proceeds to step 1912, During the allocated block, a segment of information is transmitted. Step 1910 test If the result is no, mobile unit 10 returns to base unit 1 in step 1914. 4 receives a message on the downlink and receives a message to reassign the allocation. A test is performed in step 1916 to determine if it has been received. Stage If the test result of 1916 is yes, flow proceeds to step 1908 and the mobile unit 10 again determines the distribution for a particular transmission time. The test result of step 1916 If no, step 1918 determines whether the distribution window has ended. Test is performed. If the test result in step 1918 is yes, the flow is Proceeding to step 1902, the entire process is repeated. However, the trial in step 1918 If the test result is no, flow proceeds to step 1920 and the next transmitted segment Is collected. Following step 1920, flow proceeds to the test in step 1910, The lower half of the flow shown in FIG. 19 is repeated.   FIG. 20 shows a case where the present mobile unit 10 is to be redistributed according to the present invention. Sends a new allocation message to the network, responding to the request of FIG. 1 generally illustrates a flow diagram of a method for indicating a response from a. As shown in FIG. The method starts at step 2000 and proceeds to step 200 Proceeding to 2, the network waits for a distribution request from the mobile unit. Stage 20 At 04, the network determines a distribution window for mobile unit 10, Proceed to step 2014 to determine if this distribution is to be replaced with an ongoing distribution A test is performed to perform If the test result of step 2014 is yes, Proceeds to step 2006, where the network determines a new allocation of other mobile units In step 2008, a gap is inserted in the new allocation to create a higher priority trough. Corresponding to the Next, in step 2010, the network waits for a new allocation. Insert gaps to allow other mobile units to access the reverse link at any time. You. Also, in step 2012, the network allocates a new allocation to other mobile units. Submit the schedule. After step 2012, the test result of step 2014 , The flow proceeds to step 2016 where the network inserts a gap in the new distribution To accommodate existing traffic. In step 2018, the network deploys To allow the mobile unit access to the reverse link at any time. To be able to In step 2020, the network shifts the allocation schedule. 20 and proceeds to step 2002 where the entire flow of FIG. 20 repeats. returned.   Although the present invention has been particularly shown and described with respect to particular embodiments, the spirit of the invention And various changes in form and details are possible without departing from the scope Is for those skilled in the art Can understand. Corresponding structure, material, operation and all claims in the following claims All means or steps and functional element equivalents, in combination with other claimed elements, Any structure, material or action to perform the function It is intended to be included.

────────────────────────────────────────────────── ─── Continuation of front page    (81) Designated countries EP (AT, BE, CH, DE, DK, ES, FI, FR, GB, GR, IE, IT, L U, MC, NL, PT, SE), OA (BF, BJ, CF) , CG, CI, CM, GA, GN, ML, MR, NE, SN, TD, TG), AP (GH, GM, KE, LS, M W, SD, SZ, UG, ZW), EA (AM, AZ, BY) , KG, KZ, MD, RU, TJ, TM), AL, AM , AT, AU, AZ, BA, BB, BG, BR, BY, CA, CH, CN, CU, CZ, DE, DK, EE, E S, FI, GB, GE, GH, GW, HU, ID, IL , IS, JP, KE, KG, KP, KR, KZ, LC, LK, LR, LS, LT, LU, LV, MD, MG, M K, MN, MW, MX, NO, NZ, PL, PT, RO , RU, SD, SE, SG, SI, SK, SL, TJ, TM, TR, TT, UA, UG, UZ, VN, YU, Z W (72) Tori, Dominic Michael             Liberty, Illinois, United States             Le Farlong Drive 805

Claims (1)

[Claims]   1. A method for allocating spectrum resources in a wireless communication system, :   A request for the spectrum resource to a terminal of the wireless communication system Transmitting from; and   Receiving a reply with an allocation message to allocate the spectrum resources Wherein said allocation message is a bit of a plurality of non-contiguous blocks in a window. Steps composed by map allocation;   A method characterized by comprising:   2. Wherein said spectrum resources are constructed in radio frequency bandwidth. The method of claim 1.   3. The wireless communication system is a digital communication system, The method of claim 1, wherein   4. The digital communication system is a cellular communication system, a wireless local Loop communication system, time division multiple access communication system and code division multiple access The communication system is constructed by at least one communication system. 4. The method of claim 3, wherein   5. The request for the spectrum resource is a packet channel request; The method of claim 1, wherein the method is configured.   6. The allocation message is a packet resource allocation message. The method of claim 1, wherein the method comprises:   7. The bit map distribution is provided for transmission by a second terminal 2. The method according to claim 1, wherein the gap is constituted by at least one gap. .   8. The at least one gap is a link access channel, control information Responding to at least one of a forward and a reverse link acknowledgment. The method of claim 7, wherein   9. The at least one gap reserves a portion of the spectrum resource, Providing access to a reverse link to said terminal. The described method.   10. Access to the reverse link may be an acknowledgment, transfer of control information and retransmission. Claims used for at least one of the assignment messages Item 10. The method according to Item 9.   11. 2. The terminal according to claim 1, wherein said terminal is a half-duplex terminal. The method described.   12. The terminal of claim 1, wherein the terminal is a unidirectional terminal. The method described.   13. The wireless communication system is a two-way communication system, The method of claim 1, wherein   14． Apparatus for allocating spectrum resources in a wireless communication system And:   Requesting the spectrum resource for the wireless communication Means for transmitting from a terminal of the system; and   Means for receiving a reply having an allocation message for allocating the spectrum resources Wherein said allocation message is a bit of a plurality of non-contiguous blocks in a window. Means constituted by map distribution;   An apparatus characterized by comprising:   15. A communication system for allocating resources, comprising:   A message containing information about the mobile unit's multi-slot capabilities and desired resources. A mobile unit transmitting the message; and   Receiving the message sent from the mobile unit, Providing a message containing time information and a block allocation bitmap to the mobile unit A base unit for transmitting to;   A communication system characterized by comprising:   16. The amount of the allocated resource is transmitted from the mobile unit to the base station The information about the multi-slot function of the mobile unit and the desired resource A communication system according to claim 15, wherein   17． The message transmitted from the mobile unit is a packet channel. The method of claim 15, further comprising a request message. Communications system.   18. The message transmitted from the base unit to the mobile unit is A request characterized by further comprising a packet fixed immediate assignment message. Claim 17 Communication system.   19. The base unit sends a packet channel request from the mobile unit. Send a packet fixed immediate assignment message on the same channel as 19. The communication system according to claim 18, wherein:   20. A method for allocating resources to mobile units in a wireless communication system Wherein the wireless communication system comprises a frame and a plurality of times within the frame. A method having a predetermined frame structure comprising a slot and:   Receiving information from the mobile unit;   Based on the block allocation information and the information received from the mobile unit, How multiple blocks of resources are transmitted to the mobile unit within a given frame structure Time slot availability information indicating whether the resource is to be allocated, and Generating frame start information indicating when utilization of the source should commence; and   The block allocation information, time slot availability information, and frame start information Transmitting to the mobile unit so that the mobile unit can utilize the allocated resources. The step of doing so;   A method characterized by comprising:   21. The mobile unit is a half-duplex mobile unit having a multi-slot function. 21. The method of claim 20, further comprising:   22. Time slots in the predetermined frame structure are used by other mobile units. The plurality of resource blocks in the predetermined frame structure 21. The method according to claim 20, wherein the distribution is variably distributed over the frames.   23. The need for periodic gaps in time slots within the given frame structure The plurality of resource blocks in the predetermined frame structure 21. The method of claim 20, wherein the distribution is variably distributed over the frames.   24. To allow other mobile units to use the resources, Or the half-duplex mobile unit can receive messages or make measurements. In order to be able to do so, the circumference in a time slot within the predetermined frame structure is 24. The method of claim 23, wherein a periodic gap is required.   25. The block allocation information, time slot availability information, and frame opening The starting information determines how the receiver or transmitter in the mobile unit uses the resources. 21. The method of claim 20, further comprising indicating whether to use.   26. A mobile unit for use in a wireless communication system, said mobile unit comprising: The unit is provided by transmitter / receiver means for transmitting and receiving signals to and from the base unit. 21. The block allocation information and time generated according to claim 20. Resource allocation from slot availability information and frame start information is Mobile unit characterized by further comprising a decoder providing the G.   27. A method for allocating resources to mobile units in a wireless communication system Wherein the wireless communication system comprises a frame and a plurality of times within the frame. A method having a predetermined frame structure comprising a slot and:   Based on the arrival of information addressed to the mobile unit, the allocation of the resources to the mobile unit; Determining what the knit requires;   Based on the block allocation information and the information received from the mobile unit, How multiple blocks of resources are transmitted to the mobile unit within a given frame structure Time slot availability information indicating whether the resource is to be allocated, and Generating frame start information indicating when utilization of the source should commence; and   The block allocation information, time slot availability information, and frame start information Transmitting to the mobile unit so that the mobile unit can utilize the allocated resources. The step of doing so;   A method characterized by comprising:   28. Characterized in that the method is performed in a network including a base unit 28. The method of claim 27, wherein   29. The information addressed to the mobile unit is 29. The method of claim 28, wherein the signal is emitted from a source external to the network. Law.   30. The mobile unit is a half-duplex mobile unit having a multi-slot function. 28. The method of claim 27, further comprising:   31. Time slots in the predetermined frame structure are used by other mobile units. The plurality of blocks are included in the predetermined frame structure based on whether 28. The method of claim 27, wherein the distribution is variably distributed over the frames.   32. Periodic gaps in time slots within the given frame structure are required The plurality of blocks are framed in the predetermined frame structure based on the presence or absence of the frame. 28. The method of claim 27, wherein the method is variably distributed over a system.   33. To allow other mobile units to use the resources, Or the half-duplex mobile unit can receive messages or make measurements. In order to be able to do so, the circumference in a time slot within the predetermined frame structure is 33. The method of claim 32, wherein a periodic gap is required.   34. The block allocation information, time slot availability information, and frame opening The starting information indicates how the receiver in the mobile unit uses the resources. 28. The method of claim 27, wherein indicating.   35. Mobile unit for use in a wireless communication system Wherein the mobile unit transmits and receives signals to and from a base unit. 28. The block constituted by transceiver / receiver means and generated according to claim 27 Resource allocation from allocation information, time slot availability information and frame start information And a decoder for providing the mobile unit with Mobile unit.   36. A method for allocating resources to mobile units in a wireless communication system Wherein the wireless communication system comprises a frame and a plurality of times within the frame. A method having a predetermined frame structure comprising a slot and:   Based on the information received from the mobile unit, the allocation of the resources is determined by the mobile unit. Determining what the knit requires;   Based on the block allocation information and the information received from the mobile unit, How multiple blocks of resources are transmitted to the mobile unit within a given frame structure Time slot availability information indicating whether the resource is to be allocated, and Generating frame start information indicating when utilization of the source should commence; and   The block allocation information, time slot availability information, and frame start information Transmitting to the mobile unit so that the mobile unit can utilize the allocated resources. The step of doing so;   A method characterized by comprising: