The present disclosure relates generally to wireless communications and more particularly to offsetting a packet format table, in wireless communication systems and corresponding methods.
In wireless communication systems, a set of packet formats is used at the access network (AN) and the access terminal (AT) to facilitate communication between the AN and the AT. A packet format defines the packet size, modulation, and effective coding rate of the transmitted packet. For AN based packets, the AN transmits an indication of the packet format to the AT using a control channel and transmits the associated packet using the data channel. This indication is received at the AT, and, based on the associated packet format, the AT is able to correctly process the packet received on the data channel. The control channel may also contain additional control information such as the amount of system resources used to transmit the packet.
It is generally desirable to reduce the overhead associated with indicating the packet format. To accomplish this, the set of packet formats is typically limited to a small number. For example, if there are 16 packet formats, the AN can indicate the selected packet format to the AT with 4 bits. Similarly, the AT can indicate the packet format it would like the AN to use, in the form of a channel quality indication, with 4 bits.
Limiting the set of packet formats results in quantization of the transmission properties of the packet. In particular, there are only as many combinations of packet size, modulation, and effective coding rate as can be derived from the set of packet formats.
Certain applications such as voice over internet protocol (VoIP), video telephony (VT), and gaming can have a particular packet size. If the packet size does not match one of those that can be derived from the set of packet formats, the AN must pad the packet, for example with zeros, before transmitting the packet to the AT. This results in additional overhead, thereby reducing system capacity.
The various aspects, features and advantages of the present disclosure will become more fully apparent to those having ordinary skill in the art upon careful consideration of the following Detailed Description thereof with the accompanying drawings described below. The drawings may have been simplified for clarity and are not necessarily drawn to scale.
UMB, E-UTRA, IEEE 802.20, and other communication protocols are being developed to support delivery of multiple services (VoIP, VT, and gaming) over a packet domain. Thus there is interest in schemes that support these multiple services over a shared radio channel efficiently.
For orthogonal frequency division multiple access (OFDMA) systems, the frequency domain is divided into subcarriers. For example, a 5 MHz OFDMA carrier, may be divided into 480 usable subcarriers, with a subcarrier spacing of 9.6 kHz. In the time domain, a PHY frame may be divided into multiple OFDM symbols. For example, a PHY frame may occupy 0.91144 msec and contain 8 OFDM symbols, where each symbol occupies approximately 113.93 μsec. The subcarriers are grouped to form block resource channels (BRCH) and distributed resource channels (DRCH). A BRCH is a group of contiguous subcarriers that may hop within a larger bandwidth, while a DRCH is a group of noncontiguous sub-carriers. The entire set of usable subcarriers may be divided into a certain number of DRCHs and BRCHs, each with a fixed number of subcarriers for resource allocation purposes. For example, each DRCH and BRCH may be made up of 16 subcarriers. The general term channel will be used to refer to a DRCH or BRCH. The term tile will be used to refer to 1 channel by 1 PHY frame.
For forward link (FL) transmissions (transmissions from the AN to the AT), the scheduler or other infrastructure entity in a wireless communication system assigns a certain number of channels, a certain number of PHY frames, and a corresponding packet format to a wireless communication terminal. Any entity or terminal that may be scheduled by the scheduler is referred to as a schedulable wireless communication entity. The AN transmits an indication of the assigned channels, assigned PHY frames, and packet format to the schedulable wireless communication entity using a control channel. The AT receives and processes the control channel to determine its assigned channels, assigned PHY frames, and packet format. The AT determines the packet size according to the following equation
PS=[SE(SymbolsOFDM·SubcarriersOFDM)/8]·8,
where SE is the spectral efficiency on the first HARQ transmission, SymbolsOFDM is the number of symbols in the allocation and SubcarriersOFDM is the number of OFDM subcarriers in the allocation. SymbolsOFDM is defined as the number of symbols per PHY frame times the number of assigned PHY frames, where SubcarriersOFDM is defined as the number of subcarriers per channel times the number of assigned channels. Based on the derived packet size and the modulation order corresponding to the determined packet format, the AT can process the received packet.
For certain applications, higher layer signaling is used to indicate a small set of packet formats for which the AT is to perform multiple hypothesis decoding. In this case, the control channel containing the assigned channel and assigned PHY frames may not contain an indication of the packet format. Rather, the AT attempts to decode the packet using one of the small set of packet formats. Similarly, the number of PHY frames may be fixed for certain applications, in which case the control channel need not contain an indication of the assigned PHY frames.
Referring again to
For applications such as voice and gaming, a particular packet size is required. For example, for VoIP, the packet size is determined based on the vocoder packet size and any necessary headers. For example, a VoIP packet can have a packet size of 230 bits. Using the packet formats of
There are two problems associated with using packet formats such as those shown in
To address these problems, the AN transmits an offset to the packet format table or a parameter used to calculate an offset to the packet format table to particular ATs or for particular applications using higher layer signaling. This offset to the packet format table is called a packet format offset. To indicate the packet format offset, the AN transmits at least one of the following: a spectral efficiency offset, a parameter used to calculate a spectral efficiency offset, a modulation order offset, and a parameter used to calculate a modulation order offset.
To modify the spectral efficiency of a packet format, the AN transmits a spectral efficiency offset or a parameter used to calculate a spectral efficiency offset. The spectral efficiency offset may be additive value, a multiplicative value, or any other parameter which is used to modify the spectral efficiency for a particular packet format. For example, the AN can transmit a parameter used to calculate an additive spectral efficiency offset (α) which is defined as follows:
SE
OFFSET=α(SEi−SEi−1),α<0
SE
OFFSET=α(SEi+1−SEi),α≧0′
where SEi is the spectral efficiency of the nominal packet format, SEi−1 is the spectral efficiency of the next lowest packet format, and SEi+1 is the spectral efficiency of the next highest packet format. The value of α is signaled from the AN to the AT, for example using higher layer signaling, and may be different for each packet format.
The AT receives an indication of α from the AN, for example by processing a higher layer signaling message, and determines the value of α and the corresponding packet format. Based on the determined value of α and the determined packet format, the AT determines the modified spectral efficiency for the packet format according to the following equation:
SE
MOD
=SE+SE
OFFSET′
and determines the modified packet size according to the following equation
PS
MOD
=[SE
MOD(SymbolsOFDM·SubcarriersOFDM)/8]·8.
The AN and AT may only support a certain set of packet sizes. Therefore, if the modified packet size is not one of the set of supported packet sizes, the AN and AT can establish a rule whereby the next largest supported packet size is used.
To modify the modulation of a packet format, the AN transmits a modulation offset. The modulation offset is used to maintain the spectral efficiency, while altering the modulation. The value of modulation offset is signaled from the AN to the AT, for example using higher layer signaling, and may be different for each packet format.
Referring to
Typically, the modulation offset is applied for all HARQ transmission numbers. However, in a related embodiment, the AN also indicates to the AT, for which HARQ transmission numbers the offset is valid. For example, a length 6 modulation offset bitmap is transmitted in addition to the modulation offset itself, where the least significant bit of the modulation offset bitmap corresponds to the first HARQ transmission number and the most significant bit of the modulation offset bitmap corresponds to the sixth HARQ transmission number. A ‘1’ in the modulation offset bitmap indicates that the modulation offset is valid for the corresponding HARQ transmission number and a ‘0’ in the modulation offset bitmap indicates that the modulation offset is not valid for the corresponding HARQ transmission number.
The AN can simultaneously transmit a parameter used to calculate an additive spectral efficiency offset and a modulation offset to adjust both the packet size and modulation order as depicted in
In
While the present disclosure and the best modes thereof have been described in a manner establishing possession by the inventors and enabling those of ordinary skill in the art to make and use the same, it will be understood and appreciated that there are many equivalents to the exemplary embodiments disclosed herein and that modifications and variations may be made thereto without departing from the scope and spirit of the inventions, which are to be limited not by the exemplary embodiments but by the appended claims.
The present application claims benefits under 35 USC 119(e) to U.S. provisional Application No. 60/888,173 filed on 5 Feb. 2007.
Number | Date | Country | |
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60888173 | Feb 2007 | US |