The present invention relates to wireless communication systems. More particularly, it relates to a modification to such systems by employing a physical layer (PHY) automatic repeat request (ARQ) scheme.
Proposed broadband fixed wireless access (BFWA) communication systems, using either single carrier-frequency domain equalization (SC-FDE) or orthogonal frequency division multiplex (OFDM) plan on using a high speed downlink packet access (HSDPA) application. This application will transmit downlink packet data at high speeds. In BFWA, a building or group of buildings are connected, either wirelessly or wired, and operate as a single subscriber site. The data demand for such a system is quite high for the single site's multiple end users requiring large bandwidths.
The current proposed system employs a layer 2 automatic repeat request (ARQ) system. Data blocks unsuccessfully transmitted to the subscribers are buffered and retransmitted from layer 2. The data blocks stored in layer 2 are typically large, are transmitted for high signal to noise ratio (SNR) reception, are received with a low block error rate (BLER), and are infrequently retransmitted. Additionally, layer 2 ARQ signaling is typically slow requiring large buffers and long retransmission intervals.
Accordingly, it is desirable to have alternatives in addition to a layer 2 ARQ system.
A subscriber unit for automatic repeat request mechanisms and related methods are disclosed. The subscriber unit may comprise transmitting a single carrier frequency domain equalization (SC-FDE) signals using a plurality of hybrid automatic repeat request (ARQ) mechanisms. The plurality of hybrid ARQ mechanisms may use a stop and wait architecture. Further, each of the plurality of hybrid ARQ mechanisms may transmit in a different time interval and each time interval includes at least one time slot. The subscriber unit may receive downlink data signals using hybrid ARQ and may receive acknowledgments (ACKs)/negative acknowledgments, wherein the ACK/NAKs may be received in a time period between the downlink transmissions.
The downlink physical ARQ 10 comprises a base station 12 receiving packets from the higher layer ARQ transmitter 14a provided in network 14. The packets from transmitter 14a are applied to the physical layer ARQ transmitter 12a in base station 12. The ARQ transmitter 12a encodes the data with a forward error correcting code (FEC), appends error check sequences (ECSs), modulates the data as directed by the adaptive modulation and coding (AMC) controller 12c, such as by using binary phase shift keying (BPSK), quadrature phase shift keying (QPSK) or m-ary quadrature amplitude modulation (i.e. 16-QAM or 64-QAM). Additionally, for orthogonal frequency division multiple access (OFDMA), the AMC controller 12a may vary the subchannels used to carry the packet data. The physical layer ARQ transmitter 12a transmits packets to the subscriber unit 16 through air interface 14 by way of switch, circulator or duplexor 12d and antenna 13. The transmitter 12a also temporarily stores the message for retransmission, if necessary, in a buffer memory incorporated in the transmitter 12a.
Antenna 15 of subscriber unit 16 receives the packet. The packet is input into physical layer ARQ receiver 16a through switch, circulator or duplexor 16b. At the receiver 16a, the packet is FEC decoded and checked for errors using the ECS. The receiver 16a then controls acknowledgment transmitter 16c to either acknowledge (ACK) receipt of a packet with an acceptable error rate or to request retransmission by, preferably, withholding an acknowledgment signal or transmitting a negative acknowledgment (NAK).
The ACK is sent by ACK transmitter 16c to the base station 12 through switch 16b and antenna 15. The ACK is sent via the air interface 14 to antenna 13 of base station 12. The received ACK is processed by an acknowledgment receiver 12b in the base station. The ACK receiver 12b delivers the ACK/NAKs to the adaptive modulation and coding (AMC) controller 12c and to the transmitter 12a. The AMC controller 12c analyzes the channel quality to the subscriber unit 16 using statistics of the received ACKs and may vary the FEC encoding and modulation techniques of subsequent transmissions of the message, as will be described in more detail. If the subscriber unit 16 acknowledges receipt of the packet, receipt of this ACK at base station 12 causes the original packet, which was temporarily stored in a buffer memory, to be cleared in readiness for the next packet.
If no ACK is received or a NAK is received, the physical layer transmitter 12a retransmits the original message or selectively modified version of the original message to subscriber 16. At the subscriber unit 16, the retransmission is combined with the original transmission, if available. This technique facilitates receipt of a correct message by use of data redundancy or selective repeat combining. The packets having an acceptable error rate are transferred to higher layers 16d for further processing. The acceptable received packets are delivered to the higher layers 16d in the same data order in which the data was provided to transmitter 12a in the base station (i.e. in-sequence delivery). The maximum number of retransmissions is limited to an operator-defined integer value, such as in the range of 1 to 8. After the maximum number of retransmissions are attempted, the buffer memory is cleared for use by the next packet. Decoding an acknowledgment using small packets at the physical layer reduces transmission delays and message handling time.
Since PHY ARQ occurs at the physical layer, the number of retransmission occurrences for a particular channel, retransmission statistics, is a good measure of that channel's quality. Using the retransmission statistics, the AMC controller 12c may vary the modulation and coding schemes for that channel, as shown in
To illustrate for SC-FDE, the retransmission occurrences for a particular channel are measured to produce retransmission statistics, (60). A decision on whether to change the modulation scheme is made using the retransmission statistics, (62). If the retransmissions are excessive, a more robust coding and modulation scheme is used, (64), usually at a reduced data transfer rate. The AMC controller 12c may increase the spreading factor and use more codes to transfer the packet data. Alternately or additionally, the AMC controller may switch from a high data throughput modulation scheme to a lower one, such as from 64-QAM to 16-QAM or QPSK. If the rate of retransmissions is low, a switch to a higher capacity modulation scheme is made, such as from QPSK to 16-ary QAM or 64-ary QAM, (66). The decision preferably uses both the retransmission rate and other link quality measurements signaled from the receiver, such as BER or BLER, (62). The decision limits are preferably set by the system operator.
For OFDMA, the retransmission occurrences are used to monitor the channel quality of each subchannel. If the retransmission rate or retransmission rate/link quality for a particular subchannel indicates poor quality, that subchannel may be selectively nulled from the OFDM frequency set, (64), in order to preclude use of such poor quality subchannels for some future period. If the retransmission rate or retransmission rate/link quality indicates high quality, a previously nulled subchannels may be added back to the OFDM frequency set, (66).
Using the retransmission occurrences as a basis for AMC provides a flexibility to match the modulation and coding scheme to the average channel conditions for each user. Additionally, the retransmission rate is insensitive to measurement error and reporting delay from the subscriber unit 16.
The uplink ARQ 20 is similar in nature to the downlink ARQ 10 and is comprised of a subscriber unit 26 in which packets from a higher layer ARQ transmitter 28a of the higher layers 28 are transferred to physical layer ARQ transmitter 26a. The message is transmitted to the base station antenna through switch 26d, subscriber antenna 25 and air interface 24. The AMC controller, likewise, may vary the modulation and coding scheme using the retransmission statistics of a channel.
Physical layer ARQ receiver 22a, similar to receiver 16a of
Although not shown for purposes of simplicity, the system is preferably used for a HSDPA application in a BFWA system, although other implementations may be used. The BFWA system may use frequency division duplex or time division duplex SC-FDE or OFDMA. In such a system, the base station and all of the subscribers are in fixed locations. The system may comprise a base station and a large number of subscriber units. Each subscriber unit may serve multiple users within one building or several neighboring buildings, for example. These applications typically require a large bandwidth due to the large number of end users at one subscriber unit site.
A PHY ARQ deployed in such a system is transparent to the higher layers, such as the medium access controllers (MACs). As a result, PHY ARQ can be used in conjunction with higher layer ARQs, such as layer 2. In such cases, the PHY ARQ reduces the retransmission overhead of the higher layer ARQs.
Each of the N receivers 46-1 to 46-n receives the packet in its associated timeslot. The received packet is sent to a respective hybrid ARQ decoder 50-1 to 50-n (50). The hybrid ARQ decoder 50 determines the error rate, such as BER or BLER, for the received packet. If the packet has an acceptable error rate, it is released to the higher levels for further processing and an ACK is sent by the ACK transmitter 54. If the error rate is unacceptable or no packet was received, no ACK is sent or a NAK is sent. Packets with unacceptable error rates are buffered at the decoder 50 for potential combining with a retransmitted packet.
One approach for combining packets using turbo codes is as follows. If a turbo encoded packet is received with an unacceptable error rate, the packet data is retransmitted to facilitate code combining. The packet containing the same data is encoded differently. To decode the packet data, both packets are processed by the turbo decoder to recover the original data. Since the second packet has a different encoding, its soft symbols are mapped to different points in the decoding scheme. Using two packets with different encoding adds coding diversity and transmission diversity to improve the overall BER. In another approach, the identical signal is transmitted. The two received packets are combined using a maximum ratio combining of symbols. The combined signal is subsequently decoded.
The ACK for each receiver 46-1 to 46-n is sent in a fast feedback channel (FFC) 45. The fast feedback channel 45 is preferably a low latency channel. For a time division duplex system, the ACKs may be sent in idle periods between upstream and downstream transmissions. The FFC 45 is preferably a low speed, high bandwidth CDMA channel overlaying other in-band transmissions. The FFC CDMA codes and modulations are selected to minimize interference to other in-band transmissions. To increase the capacity of such a FFC 45, multiple codes may be used.
The ACK receiver 56 detects the ACKs and indicates to the corresponding transmitter 40-1 to 40-n whether the ACK was received. If the ACK was not received, the packet is retransmitted. The retransmitted packet may have a different modulation and coding scheme as directed by the AMC controller 12c, 26c. If the ACK is received, the transmitter 40-1 to 40-n clears the previous packet from the buffer and accepts a subsequent packet for transmission.
The number of transmitters and receivers N is based on various design considerations, such as the channel capacity and ACK response time. For the preferred system previously described, a 2-channel architecture is preferably utilized, with even and odd transmitters and receivers.
The PHY ARQ technique of the preferred embodiment provides a 7 db gain in signal to noise ratio (SNR) as compared to a system using only higher layer ARQ. This occurs by operating at higher block error rates (BLERs) (5-20% BLER) and using smaller block sizes for layer 1 than is practical with higher layer ARQ alone. The decreased SNR requirement allows for: increased capacity by switching to high order modulation employing an adaptive modulation and coding (AMC) technique; lower customer premise equipment (CPE) costs by using lower grade RF (radio frequency) components with the PHY ARQ compensating for reduced implementation performance; increased downlink range which extends the cell radius; reduced downlink power in the base station (BS) to minimize cell-cell interference; and increased power amplifier (PA) back-off when employing a multi-carrier technique.
This application is a continuation of U.S. patent application Ser. No. 13/356,206, which was filed on Jan. 23, 2012 and is a continuation of U.S. patent application Ser. No. 12/683,711, filed on Jan. 7, 2010, issued as U.S. Pat. No. 8,102,801 on Jan. 24, 2012, which is a continuation of U.S. patent application Ser. No. 10/084,043, filed on Feb. 27, 2002, issued as U.S. Pat. No. 7,672,265 on Mar. 2, 2010, which is a continuation of U.S. patent application Ser. No. 09/939,410, filed on Aug. 24, 2001, all of which are incorporated by reference herein as if fully set forth.
Number | Date | Country | |
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Parent | 13356206 | Jan 2012 | US |
Child | 15614010 | US | |
Parent | 12683711 | Jan 2010 | US |
Child | 13356206 | US | |
Parent | 10084043 | Feb 2002 | US |
Child | 12683711 | US | |
Parent | 09939410 | Aug 2001 | US |
Child | 10084043 | US |