JPH07509595A - Method and apparatus for conveying data fields in a communication system - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed description of the invention] Method and apparatus for conveying data fields in a communication system field of invention TECHNICAL FIELD The present invention relates generally to communication systems, and more particularly, to communication systems. Concerning communicating data fields.

Background of the invention Time division multiplexing (TDM: lime division multiple) Digital communication systems, such as must be transmitted on a radio frequency (RF) carrier signal. specific encoding rate time slots (and time periods) are chosen to sufficiently satisfy the time constraints of the TDM time slots. transmission of audio information is not a problem for the system. However, the Times Large multiple slots during timeslots where the lot is small compared to the message. If a message needs to be sent, the system will have a problem. The message is In general, a specific layer of a communication system (here, a layer is a layer of a communication system) is a convenient separation between functions regarding different levels), so A common solution involves a specific layer above the air interface (e.g. l1 in), or segmentation at the data link layer. ation) method is performed.

Such a scheme is inappropriate for two reasons. First of all, these methods reencodes the original message into multiple data link layer messages, each of size is smaller than one time slot. A layer at the receiving unit replays the message. To construct, layer n information is conveyed with each transmitted time slot.

Therefore, the number of bits to send is the number of bits in the layer n header and the number of bits to send the message. multiplied by the number of segments (or timeslots) required to It will be done. Second, if the layer n message is not sent correctly, the fin entity will The entire message, including all timeslots required to send the message. I have no choice but to retransmit my body. The timeslot channel is a ring with a high pit error rate. Due to the nature of the Ru.

P E D C (Pan-European Digital Ce1lula r) System specified GSM (group 5 special mobile) improves the above by making only one window size available. It is a layered protocol that addresses the problem. This is essentially a positive response of the control function. response/no-acknowledgment It's rotocol.

For user data service applications, GSM provides data services from subscriber units. Layer 24J up to internetwork functions for services! perform Noh. Therefore, A true point-to-point connection exists from the ingress unit to the base station. t-tO-point) with layer 2 function and 17N l/). AMP S etc. communication systems are not hierarchical, which is why today's complex communication systems There is no structure that allows for the necessary flexibility.

Therefore, without increasing the number of bits transmitted, and even if errors occur, the entire message can be Rings with high bit error rates during relatively small time slots do not need to be retransmitted. A communication system is required that sends multi-slot messages at .

Brief description of the drawing FIG. 1 shows the method used to perform message segmentation according to the present invention. A communication system is shown below.

FIG. 2 shows message segmentation according to the present invention.

The transceiver (transmitter/receiver) used in the communication system shown in Figure 1 employs machine).

FIG. 3 shows the specific radio frequencies used by the communication system of FIG. (RF) shows a series of frames transmitted by a shim to a carrier.

FIG. 4 shows the structure of a frame used by the communication system of FIG.

FIG. 5 shows the downlink time slot used by the communication system of FIG. The structure of the cut is shown below.

FIG. 6 shows a modified downlink used by the communication system of FIG. m1 according to the present invention. shows the structure of a link timeslot.

FIG. 7 shows a modified app for use with the communication system of FIG. 1 according to the present invention. shows the structure of a link timeslot.

FIG. 8 shows a modified downlink timeslot of FIG. 6 and a seventh downlink time slot according to the present invention. The figure shows the structure of the second control information field of the modified amplifier link timeslot. .

FIG. 9 illustrates the segmentation of data fields according to the present invention.

FIG. 10 shows the segmentation of data to generate data fields according to the present invention. This shows the recombination of the

FIG. 11 shows another embodiment of a modified downlink timeslot according to the present invention. vinegar.

Detailed description of the preferred embodiment A communication system according to the invention divides a layer, e.g. layer 2, into upper and lower sub-layers. divide. The upper layer contains address and flow control functions that cover the entire message. Messages can be sent from one or more slots. Become. Lower layer 2 is aware that the retransmission of segments of data is based on time rather than the entire message. Error correction and and retransmission functions.

The tIS1 diagram shows a communication system 100 that advantageously employs the present invention. good practice In an example, communication system 100 includes a time division multiplexed (TDM) personal communication system. Stem (PO2: personal communication system m). Therefore, the main purpose of PO2 is slow moving and/or fixed reception. / servicing a sending unit, e.g. unit 103.106. Ru. Therefore, the unit 103 is a mobile subscriber unit used by pedestrians. unit 106 can be used as a wireless local loop, for example. This is a fixed subscriber unit that can be used. For convenience, units 103 and 106 are as follows: In this case, the subscriber unit is represented as 103°106.

FIG. 2 shows a transceiver (transmitter/receiver) 200 that advantageously employs the present invention. vinegar. The top portion of FIG. 2 generally represents transmitter section 204 of transceiver 200. suitable In one embodiment, the base station 109i 112 and the subscriber unit 109i 103.

106 utilizes transceiver 20 shown in FIG. Also, in a preferred embodiment , base stations 109 and 112 are the same. As shown in Figure 2, during transmission, The information 201 is input to a segmentor 202, and this segment The printer 202 segments the data fields contained in the upper layer information 201. . The multiplexer MUX 203 receives the data generated by the segmenter 202. segments of data for transmission as shown in Figure 9. Prepare. Upper layer information (UL I: upper layer information ation) 201 is the ULI of time slots O to 9 as shown in FIG. are shown as only one input for convenience. Next, the output of MUX203 The power is entered into data input 206, which input 206 is the user information field. Add a second control information field for each segment of data sent in . The output of data input 206 is input to a conventional modulator 212, mixer 218 and and is frequency-amplified by an intermediate frequency (IF) signal 215. , IF 221, mixer 227 and local oscillator (LO) 224. is again up-converted in frequency. The output of mixer 227 is the power - input to a conventional power amplifier, shown as output 230, to a conventional antenna 2. 33 to the receiving unit. The controller 209 is a segmenter. 202. Controls the operation of MUX 203 and also provides LO 224 to mixer 227 . In a preferred embodiment, controller 209 is a Motorola 68000 series controller. It is a micro-pro sensor.

The lower portion of FIG. 2 generally represents receiver section 234 of transceiver 200. In Figure 2 As shown, the signal 236 transmitted by the transmitter section 204 is transmitted by a conventional antenna. 233 and input to RF input 235 . The RF input 235 is For example, a typical front end for a duplexer, splitter, etc. (not shown) Built-in receiver. The output of RF input 235 is input to mixer 239, which It is then down-converted by the LO 242. The output of mixer 239 is lF2 45, its output is input to mixer 251, and output to IF signal 248. Therefore, it is down-converted again. The output of mixer 251 is input to demodulator 254. and demodulate this signal. The output from the demodulator 254 is sent to a demultiplexer ( DEMUX) 257, and this demultiplexer 257 Basically, the multiplexing function performed by the MUX 203 of No. 4 is cancelled. DEMUX The output of 257 is actually for each time slot 0-9 as shown in FIG. However, for convenience, it is shown as only one output in FIG. 2). Next G , the output from the DEMUX 257 becomes the transmitted segment of data, which also is input to the combiner 263, where it is Composed into the original data field. The details are shown in FIG.

FIG. 3 shows specific radio frequency (RF) keys used in the communication system of FIG. The figure shows a series of frames transmitted on a carrier. one transmitted on a particular RF carrier. The series of frames represents signal 236 shown in FIG. The t/g4 diagram is shown in Figure 3. The structure of the frame is shown. In FIG. 4, the basic structure of frame 403 is There are 10 TDM time slots per carrier or channel. 500 To provide voice at 32Kbps in slots/second, the RF channel As shown in the figure, 500Kbps capacity, i.e. 10 time slots/frame The configuration requires 50 Kbps per time slot. As a result, 3 2Kbps audio and its fields are possible. Audio encoding is 32Kbp Adaptive delta pulse code modulation (ADp CM: Adaptive D e+ta Pulse Code Modulation) It will be done. In the preferred embodiment, particular timeslots O through 9 of timeslots 406 The time period of is 200 microcedar, so that the period of frame 403 is 2 It will be milliseconds.

FIG. 5 shows a data field consisting of at least control information and user information. 2 shows a conventional downlink timeslot with As shown in Figure 5, 14 The bits represent the frame initialization bits of subscriber units 103 and 106 and are reference It is represented by reference number 501. There are 9 bits in the control information field 503. This is a system control field in the preferred embodiment. In a preferred embodiment, The 9 bits in control information field 503 are allocated as follows: (1) The 5 bits are a digital color code used to represent a specific base station. (2) 1 bit is used to represent one of 32 combinations of user information or (3) The l bit is used to represent the transmission of either control information or control information. Used to indicate that the user information provided is either voice or data. (4) 2 bits are segmentation control (roll-continuation slot, r ol, J - start slot, rlOJ - end slot), rlN - single slot) used to represent

With further reference to FIG. 5, 64 bits represent user information field 506; For example, voice, user data or robbed control data signals. This is used to send nrrol clalasignaling). These bits correspond to a multiplexing bit rate of 32 Kbps/time slot. Ru. 12 bits 509 are for error detection and synchronization by the receiving unit; The last l bit 512 is used for power control of the power control channel (FCC). It will be done.

FIG. 6 shows a modified downlink timeslot 600 according to the present invention. Dow The downlink timeslot 600 is the downlink timeslot shown in FIG. 500, but a second control information field 606 indicates the downlink time. It has been added to slot 600. In a preferred embodiment, the first control information field 603 is the same as the control information field 503 and therefore the system control field. represents the field. The second control information field 606 is a segmentation control field. represents the field. FIG. 7 shows a modification in which a second control information field 709 has been added as well. Indicates positive amplifier link timeslot. Represented by reference number 609,720 The 56-bit field shown in Figures 6 and 7 corresponds to the unit described in Figure 5. This is the remainder of the user information field 506. Second control information field 606, 70 9 is shown in Figure 8, and the series of commands and corresponding bit values are shown in Table 1 below. Describe it.

In the preferred embodiment, the second control information fields 606, 709 are standard HDL Either the C layer protocol or the LapB/LapD protocol.

The HDLC protocol is the American ANS I standard, and is a The pD protocol is described in CCTTT Recommendation X, 25 and is a European standard. It is. The second control information fields 606 and 709 contain the time slots shown in FIG. 406 in each time slot 0-9. Therefore, if the information is e.g. 109 to subscriber unit 103 (or vice versa), the transmission/ The receive sequence number is based on timeslots, not on the entire message. exchanged based on

The operational scenarios flow from higher to lower layers as follows:

The message is a user application (UserApplication) , generated at layer 3 or layer 2 level. User application or layer 3 If the message is generated at the level 2, the message goes down to layer 2 and waits in the layer 2 transmit buffer. O that is put in the transmission buffer queue A message can also be generated at layer 2 and still not queued in the send buffer. It will be done. This send buffer queue is actually categorized according to message type. consists of various priority queues, It is located in the data input 206 of the transmitter section 204 in FIG.

FIG. 9 illustrates the segmentation of data fields according to the present invention. 9th As shown in the figure, upper layer information (ULI) 201 includes time slot O shown in FIG. Consists of ULIs from ~9. The ULI for each time slot O-9 is About MuslotMessage format +er) 903. The output from the formatter 903 is the segmenter 2 02 and the data file for transmission in fields 609, 712. field (ULI) into a segment of data. MUX203 is a data segment ment to the rest of the user information field 609.712, resulting in " The frame will be substantially similar to the frame of FIG. In a preferred embodiment, Segmenter 202 divides the data field or ULI into 56 bits of data. Make it into segments. MUX 203 multiplexed segments of data into frames After that, the data input 206 is inputted by the second width 1j control information field 606,709. Add the represented lower layer information (LLI) to the segment of data. Second control information frame The presence of fields 606 and 709 indicates that some of the time slots may be received in error. Transparent to message sending except when In such a case, the second control The information is retransmitted based on the information content of the REJ (reject) message. request. The length of the data field (i.e. the length of the message) is also Transparent to control information field 606. The timeslot number is Continuous across Tsage boundaries. The first slot of Message, e.g. In the case of lot 908 or in the case of a single slot information message, the second slot shown in FIG. The rFJ bit in the control information field 606 indicates the Used to represent the opposite bit state of the last bit. The remaining bits are It is a bit (fill b mouth). Therefore, if the rFJ bit is "1", The fill bit consists of an "O". If the rFJ bit is '0', the fill bit is made up of "1". The timeslot is filled with exactly the correct number of bits. , the rFJ bit has the opposite value of the last bit in the message.

The recombination of segmented data in a data field is shown in FIG. D EMUX257 separates the demodulated timeslot 2 into individual timeslots. However, the data output 260 is the 21st vlJ information field 606, 709 (sun That is, the control information is read from LL11003) in FIG. user feel The segmented data in nodes 609 and 712 is stored in the recombiner buffer. 263, where the segments are stored until the entire message is received. will be paid. When the entire message is received, the message formatter 1000 formats the segment into all fields of data. In this way, the self Each segment of data transmitted in a timeslot and having its own unique control field The elements are recombined into a data field at the receiving unit.

In another embodiment, the downlink timeslots are modified as shown in FIG. You may. Another downlink timeslot 110 as shown in FIG. 0 sets the segmentation control 1103 separate from the 9 system control bits. and configured in the second control information fields 606 and 709. remaining 6 bits Note is the LapD control field 1106, which is shown in FIG. 2 control information fields 606 and 709. Figure 8, 2nd 2 bits from control information fields 606, 709 (N (R) and N (S) 1 bit from each) is the downlink times shown in Figure 11. Standard HDLC protocol or LapD/La Operation as a pB protocol is still maintained.

The present invention has been particularly described with reference to particular embodiments and alternative embodiments. may vary in form and detail without departing from the spirit and scope of the invention. It will be understood by those skilled in the art that many modifications are possible.

Figure 5 Tau/Su/Ri・

Claims (10)

[Claims] 1. Has a data field consisting of at least control information and user information In time division multiplexing (TDM) communication systems that use time slots, data 1. A method for transmitting data fields, the method comprising: segmenting the data field into segments of data; Add a second control information field to each segment of the field with user information and during a time slot of the TDM communication system, the second control transmitting a segment of data including an information field; A method characterized by comprising: 2. The control information substantially relates to control of the TDM communication system, and the control information substantially relates to the control of the TDM communication system, and The information field describes the reception of the transmitted segment of data at the receiving unit. Regarding control, the control of reception includes error correction and replay at the receiving unit. Claim 1, further comprising control regarding a transmission function. the method of. 3. The second control information field is based on standard HDLC layered protocol or L Claim 1 comprising either one of apB/LapD protocols. Method described. 4. Has a data field consisting of at least control information and user information transmitting a data field in a time division multiplexed (TDM) communication system Apparatus for: segmenting said data field into segments of data; means to Add a second control information field to each segment of the field with user information and means for controlling the second control during a time slot of the TDM communication system. means for transmitting segments of data containing information fields; A device characterized by comprising: 5. The control information substantially relates to control of the TDM communication system, and the control information substantially relates to the control of the TDM communication system, and The information field describes the reception of the transmitted segment of data at the receiving unit. Regarding control, the control of reception includes error correction and replay at the receiving unit. Claim 4, further comprising control regarding a transmission function. equipment. 6. The second control information field is based on standard HDLC layered protocol or L Claim 4 comprising either one of apB/LapD protocols. The device described. 7. Receiving data fields in a time division multiplexed (TDM) communication system The method comprises: transmitting first control information during a time slot of the TDM communication system. field, a second control information field within a portion of the user information field, and the remainder. a segment of data in the first user information field; controlling functions related to TDM communication based on the control information field; and Beauty recombining the received segments of data based on the second control information field; generating the data field; A method characterized by comprising: 8. Receiving data fields in a time division multiplexed (TDM) communication system A device that: a first control information field and a user during a time slot of the TDM communication system; A second control information field within a portion of the user information field and the remaining user information field. a segment of data in the field; and means for receiving a segment of data in the first control information field; means for controlling functions related to TDM communication based on the code; and recombining received segments of data based on the second control information field; means to A device characterized by comprising: 9. Time slot with system control field and user information field In a time division multiplexed (TDM) communication system that uses A device that sends a field of message data, the field of message data being an apparatus having an interval longer than a TDM time slot, wherein the message data a means of segmenting fields into segments of data; Add a segmentation control field to some of the user information fields. and means for controlling the system control during a time slot of the TDM communication system; control field, the segmentation control field, and the remaining user information. and means for transmitting segments of data within the field; A device characterized by comprising: 10. The means of sending is in response to a resend request, and is not sent in units of messages, but in time. further comprising means for retransmitting the segment of data on a per-slot basis; 10. The device according to claim 9, characterized in that: