Patent Application
20080240013
The present invention relates generally to power control in a mobile communication system and, more particularly to a method and apparatus of closed loop power control for a transmitting station that is capable of operating in a compressed mode.
A known problem with WCDMA phones is excessive power consumption that results in undesirable current drain and short battery life. When engaged in normal voice communications, a WCDMA phone typically transmits and receives continuously. This continuous operation is one of the primary reasons for the undesirable current drain in WCDMA phones. A related reason for current drain is the presence of a duplexer in the transmit path that increases path loss.
U.S. patent application Ser. No. 11/614,488 describes a method of reducing power consumption in a WCDMA phone by allowing the mobile stations to switch to a compressed mode of operation during periods when the reverse link load is light. In the compressed mode, the mobile stations transmit intermittently with a desired duty factor rather than continuously and increase their transmit power during the “on” periods to maintain the same data rate.
One problem with compressed mode operation is that it disrupts the closed loop power control mechanism for controlling the transmit power of the mobile station. The base station monitors the strength of the received signal strength from the mobile station and varies the transmit power level of the mobile station inversely in proportion to the observed variations in received signal strength. With fast power control, the base station sends approximately 1600 power control commands per second. When the mobile station operates in a compressed mode, there will be intermittent “on” and “off” periods in the transmission from the mobile station. During the “off” periods, the power control mechanism will try to increase the mobile station transmit power. During the “on” periods, the base station will see power levels higher than expected and try to decrease the mobile station transmit power level.
Accordingly, there is a need for a power control mechanism that can accommodate compressed mode operation by a mobile station.
The present invention relates to closed loop power control in a mobile communication system that can be adapted when a transmitting station is operating in a compressed mode. The receiving station (mobile station or base station) measures the signal strength of the received signal from the transmitting station (base station or mobile station), generates periodic power control commands based on the signal strength measurements, and transmits the power control commands to the transmitting station to adjust the transmit power level of the transmitting station. When the transmitting station is operating in a burst mode, the receiving station dynamically adapts a power control filter for filtering signal strength measurements to compensate for the intermittent transmission by the transmitting station.
The present invention provides a method of reducing power consumption in a radio communication system. The present invention is described herein in the context of a WCDMA radio communication system, though the techniques may be applied in other radio communication systems. Further, this application explains how the principles of the present invention can be applied to a voice channel in a WCDMA system. However, the principles described herein may also be applied to other types of information, such as audio, video, and other data.
U.S. patent application Ser. No. 11/614,488 titled COMPRESSED MODE FOR REDUCING POWER CONSUMPTION filed Dec. 21, 2006 describes a method of reducing power consumption in a WCDMA phone by allowing the mobile stations 30 to switch to a compressed mode of operation. Compressed mode is one form of burst mode transmission. In the compressed mode, the mobile stations 30 transmit intermittently with a desired duty factor rather than continuously, and increase their transmit power during the “on” periods to maintain the same data rate. This application is incorporated herein in its entirety by reference. To briefly summarize, the base station 20 continuously monitors the uplink load and sends control signals to one or more mobile stations 30 to selectively enable and disable compressed mode operation depending on the uplink load. In general, compressed operation is enabled when the base station 20 has excess capacity on the uplink given the current loading conditions. If the uplink is heavily loaded, compressed mode is disabled. When the compressed mode is enabled, the mobile stations 30 individually switch between the compressed mode (e.g. intermittent transmission) and normal mode (e.g., continuous transmission) on the uplink depending on the current transmit power level of the mobile station 30. When the current transmit power of the mobile station 30 is low and the mobile station 30 has sufficient power headroom, it uses compressed mode for uplink communications. Otherwise, the mobile station 30 transmits in normal mode on the uplink.
In compressed mode, the mobile station 30 transmits intermittently in accordance with a defined compression pattern.
The compressed mode of operation can potentially interfere with closed loop power control mechanisms implemented in WCDMA systems. WCDMA systems typically implement fast power control to maximize system capacity. With fast power control, the transmit power level of the transmitting station may be updated at a frequency of 1600 times per second. The general idea is that the power control mechanism will track changes in channel conditions to maintain the received signal strength at a desired level. When the transmitting station operates in a compressed mode, the closed loop power control mechanism will continue to track changes in the received signal power. During off periods, the closed loop power control algorithm at the receiving station will try to increase the transmit power of the transmitting station. During on periods, the transmitting station may increase its transmit power to maintain the same data rate. Thus, the received signal strength at the receiving station will be higher than expected and the receiving station will try to decrease the transmit power of the transmitting station.
According to the present invention, a fast power control algorithm is used when the transmitting station is operating in a normal transmission mode. In order to prevent the power control algorithm from tracking the on and off periods during compressed mode, a filter can be applied to the signal strength measurements in the compressed mode of operation. The filtering needed may be dependent on both the frequency and duty factor of transmission in the compressed mode. In the example shown in
The duty factor also affects the length of the filter that needs to be applied. For example, a compressed mode transmission with a burst frequency of 10 msec and a duty factor of 10% provides only one 1 msec burst over 10 msec period for which signal strength measurements can be made. In contrast, a compressed mode transmission with a burst frequency of 10 msec and a duty factor of 50% provides 5 msec of data in the same 10 msec period. In the first case, filtering over a 10 msec period may not provide enough data to ensure reliable power control. In the second case, filtering the signal strength measurements over 10 msec may allow the receiver to generate power control signals with a reasonable degree of confidence. Achieving the same confidence level in the first case would require that data be filtered over a 50 msec period.
The power adjustment circuit 56, shown in
During compressed mode operation, the closed loop control circuit 60 will respond more slowly to changes in channel conditions. Thus, the commanded power level must be adequate for a longer period of time. Consequently, it may be desirable to adjust the target SNR during compressed mode operation to provide greater margin in case the channel conditions worsen before the next power control command is sent. The amount of the margin may be determined by the group delay of the power control filter 54. In one embodiment, the control unit 55 generates a target value adjustment factor based on the compressed mode parameters and/or the filter parameters. This target value adjustment factor is used by the open loop control circuit 62 to adjust the target value for the closed loop power control when the transmitting station is operating in the compressed mode.
The digital section 104 comprises baseband circuit 120 and a control circuit 122. The baseband circuit 120 and control circuit 122 may comprise one or more processors or processing circuits. The baseband circuit 120 processes signals transmitted and received by the transceiver station 100. The baseband circuit 120 encodes, modulates, and spreads the transmitted signals. On the receiver side, the baseband circuit 120 despreads, demodulates, and decodes received signals. The baseband circuit 120 also implements a vocoder 124 for encoding and decoding speech signals. The control circuit 122 controls the overall operation of the transceiver station 100. The control circuit 122 includes a power control circuit 50 as shown in
The present invention has been described in the context of a conventional voice channel for WCDMA. Release 7 of the WCDMA standard has a mode called Continuous Packet Connectivity (CPC) mode, which is described in the Third Generation Partnership Project (3GPP) Technical Report 25.903 (Mar. 22, 2007). The CPC mode will enable voice over IP (VoIP) in existing R′99 UMTS networks. Like the compressed mode described above, CPC mode is another form of burst mode transmission. Voice packets will be transmitted in bursts on the uplink channel. ACK and NACK bursts may be interleaved with data bursts. The burst pattern may vary in duty factor and burst frequency depending on factors such as system loading, mobile station power, etc.
Those skilled in the art will appreciate that compressed mode operation as described herein represents a trade-off between power savings and system capacity. A heavily loaded system that is operating near its capacity should use the normal transmission mode and fast power control to maximize system capacity. The compressed modes of operation, in general, are desirable when the system is lightly loaded and has excess capacity. During periods of light load, the unused system capacity can be sacrificed for the purpose of saving power by switching to the compressed mode. The parameters of the compressed mode operation may be controlled by the network depending on the system capacity. For example, a lightly loaded system may be able to operate in a compressed mode with a duty factor of 25%. The same system at a moderate load may be able to operate in a compressed mode using a 50% duty factor. A heavily loaded system may disable the compressed mode.
The present invention may, of course, be carried out in other specific ways than those herein set forth without departing from the scope and essential characteristics of the invention. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, and all changes coming within the meaning and equivalency range of the appended claims are intended to be embraced therein.
