KR200391801Y1 - Wireless communication for controlling transmission power of a downlink signaling channel based on enhanced uplink transmission failure statistics - Google Patents

Abstract

A method and system are provided in which transmission power of at least one downlink (DL) enhanced uplink (EU) signaling channel is controlled so that enhanced dedicated channel (E-DCH) DL signaling is effectively and reliably delivered. The system includes at least one wireless transmit / receive unit (WTRU), at least one Node-B and a radio network controller (RNC). At least one WTRU and Node-B compute EU transmission error statistics on the DL EU signaling channel and report EU transmission error statistics to the RNC. The RNC then adjusts the transmit power offset of the DL EU signaling channel for use in determining the transmit power of the Node-B's DL EU signaling channel based on the EU transmit error statistics.

Description

WIRELESS COMMUNICATION FOR CONTROLLING TRANSMISSION POWER OF A DOWNLINK SIGNALING CHANNEL BASED ON ENHANCED UPLINK TRANSMISSION FAILURE STATISTICS}

The present invention relates to a wireless communication system including a wireless transmit / receive unit (WTRU), at least one Node B, and a radio network controller (RNC), and more particularly to enhanced uplink (EU) transmission. Enhancing Dedicated Channel (E-DCH) downlink signaling channel by controlling the transmit power of downlink (DL, DownLink) EU signaling channel and scheduling information reception error statistics reported to RNC by WTRU and / or Node-B To a method and system in which their reliability is further enhanced.

Methods of improving uplink (UL) coverage, throughput, and transmission latency are currently being investigated in Release 6 of 3GPP. To achieve these goals, Node-B is responsible for scheduling and allocation of uplink resources from WTRUs. The RNC remains unsophisticated throughout the control, but the Node-B can make better decisions and manage UL radio resources on a short-term basis better than the RNC.

A new media access control (MAC) function / entity for media access control (MAC), called Enhanced Uplink (EU), is created at Node-B and WTRU that handles the transmission and reception of E-DCH transmissions. . In order to adequately support the EU, information such as channel assignments, transmission feedback (ie, acknowledgment or non-acknowledge), and other feedback information (such as power control commands or channel quality) may be used in the DL EU. It must be transmitted effectively and reliably through the signaling channel.

Power control on the shared DL EU signaling channel is essential to support proper operation of the DL EU signaling channel. Power control reduces interference overall, allowing more efficient use of radio resources.

The present invention relates to a method and system for controlling the transmit power of at least one DL signaling channel so that E-DCH DL signaling can be efficiently and reliably delivered to the WTRU. For DL signaling dedicated to certain WTRUs, the transmit power of the DL EU signaling channels is based on the current DL dedicated control channel power plus power offset. For DL signaling common to a plurality of WTRUs, the transmit power of the DL EU signaling channels is based on the power setting by the RNC plus power offset. The RNC monitors EU transmission error statistics reported from the Node-B and the WTRU to estimate NACK to ACK misinterpretation statistics (ie, statistics of misinterpretation of NACKs as ACKs).

Node-B reports statistics of EU transmission errors at Node-B to the RNC, and the WTRU reports statistics of EU transmission errors at the WTRU to the RNC. The RNC then adjusts the NACK to ACK power ratio according to the interpretation error statistics from NACK to ACK. Node-B can either receive failed scheduling information (i.e., channel allocation information), receive statistics by detecting when the WTRU has not initiated EU transmission after Node-B transmits channel allocation information to the WTRU, or E-DCH transmission. Compute the data rate / frequency which is not the same as listed in the channel assignment information.

The WTRU may also calculate failed scheduling information reception statistics by detecting when there is no response to EU channel allocation requests in the request following a particular time period. The RNC monitors failed scheduling information reception statistics reported by the WTRU and Node-B to estimate statistics of scheduling information reception errors. The RNC adjusts the power offset of the scheduling information field based on the statistics of the scheduling information reception error.

In the following, the word "WTRU" refers to any type of device capable of operating in a user equipment (UE), mobile station, fixed or mobile subscriber unit, pager, or wireless environment. Include. In the following, "node-B" includes, but is not limited to, a base station, a site controller, an access point, or any other kind of interface device in a wireless environment.

Features of the present invention may be embedded in an integrated circuit (IC) or may be configured in a circuit that includes a plurality of interconnecting components.

1 is a block diagram of a wireless communication system 100 in accordance with the present invention. System 100 includes a WTRU 102, at least one Node-B 104 and an RNC 106. The RNC 106 operates the entire EU by configuring EU parameters such as the initial transmit power level, the maximum allowable EU transmit power or the available channel resources per Node-B for the Node-B 104 and the WTRU 102. To control. Between WTRU 102 and Node-B 104, Dedicated Physical Control Channel (DPCCH) 114, E-DCH 108, UL EU Signaling Channel 112 and DL EU Signaling Channel 110 ) Is established.

For E-DCH transmissions, the WTRU 102 sends an E-DCH allocation request to the Node-B 104 via either the E-DCH 108 or the UL EU signaling channel 112. In response, the Node-B 104 sends channel assignment information to the WTRU 102 over the DL EU signaling channel 110. After EU radio resources are allocated for the WTRU 102, the WTRU 102 sends data over the E-DCH 108. In response to the E-DCH transmission, Node-B 104 transmits an ACK or NACK for a Hybrid-Automatic Repeat Request (H-ARQ) operation over DL EU signaling channel 110.

When the WTRU 102 is configured to operate on the E-DCH 108 by the RNC 106, the power offset (eg, ACK / NACK, scheduling information, etc.) of each information field transmitted over the DL EU signaling channel 110. And the like are also configured by the RNC 106 and communicated to the Node-B 104 via the Iub / Iur 118. Such initial power offsets are determined by the RNC 106 based on the required error probability of the information fields. During operation of the E-DCH 108, the power offsets of the information field in the DL EU signaling channel 110 need to be adjusted according to the actual experienced QoS of the DL EU signaling channel 110.

For DL signaling dedicated to certain WTRUs 102, the transmit power of the DL EU signaling channel 110 is based on the current DL dedicated control channel power and power offset. For DL signaling common to the plurality of WTRUs 102, the transmit power of the DL EU signaling channels 110 is based on power level setting and power offset by the RNC 106.

For each WTRU 102, the transmit power of the DL EU signaling channel 110 is individually controlled. The transmit power of the DL EU signaling channel for a particular WTRU 102 is determined as the transmit power and power offset of the DL Dedicated Physical Control Channel (DPCCH) 114 of the WTRU 102. In this respect, the power of the DPCCH is used as a reference. The transmit power of the DPCCH of the WTRU 102 is controlled as in Release 99/45 of the Universe Mobile Telecommunication Service (UMTS).

Other power offsets are used and transmitted by the Node-B 104 depending on information such as ACK / NACK, channel quality feedback, scheduling information, and the like. In the ACK / NACK information field, a higher power offset is used to send a NACK rather than sending an ACK, which is the NACK to ACK misinterpretation statistics (i.e., the error of misinterpreting NACK as ACK). Causes more serious problems than ACK to NACK misinterpretation statistics (that is, statistics that misinterpret ACK as NACK).

2 is a signaling diagram of step 200 by a system 100 implementing transmit power control on a DL EU signaling channel 110 according to the present invention. RNC 106 communicates the initial configuration of power offsets for DL EU signaling channel 110 to Node-B 104 (step 202). The RNC 106 reports the failed MAC-e transmission and / or failed channel reported by the WTRU 102 and / or Node-B 104 to estimate the likelihood of error in reception and transmission on the DL EU signaling channel 110. The allocation information reception statistics are monitored (steps 204 and 206). In step 207, the RNC 106 estimates the statistics of the NACK to ACK interpretation error based on the reported failed MAC-e transmission statistics. If the statistical estimate of the NACK to ACK interpretation error is higher than the threshold, then the RNC 106 adjusts the NACK to ACK power ratio (ie, the ratio of power offset) for the DL EU signaling channel 110 accordingly. Based on the failed channel allocation information reception statistics received from the WTRU 102 and the Node-B 104, the RNC 106 adjusts the power offset of the scheduling information field accordingly (step 208). In this way, proper operation of the EU is maintained and radio resources are effectively utilized.

3 is a flowchart of step 300 for controlling transmit power of a DL EU signaling channel according to an embodiment of the present invention. The WTRU 102 is configured for EU operation (step 302). The WTRU 102 determines whether there is data transmitted over the E-DCH 108 v (step 304). If there is data to be transmitted, the WTRU 102 sends a channel assignment request to the Node-B 104 via either the E-DCH 108 or the UL EU signaling channel 112 (step 306). Node-B 104 receives the request and sends channel assignment information to WTRU 102 over DL EU signaling channel 110 (step 308).

After sending the channel assignment request, the WTRU 102 monitors the DL EU signaling channel 110 for channel assignment information. Node-B 104 also monitors the E-DCH transmission after transmitting channel assignment information over DL EU signaling channel 110 (step 310).

Channel assignment information sent to the WTRU 102 may not be successfully delivered. The progress of the unsuccessful transmission of channel assignment information depends on how the assignment is performed. In deterministic assignment, the WTRU 102 will not transmit at all. In statistical allocation, the WTRU 102 may transmit data at no rate or persistence level at all or not at the same level as listed in the channel assignment information. Deterministic allocation is an allocation that the WTRU 102 can transmit at any time as long as the maximum allocated transmit power and / or data rate is specified and its transmit power and / or data rate does not exceed its maximum. Statistical allocation is an assignment in which a persistence level (possibility) is also specified, in addition to a specific maximum allocated transmit power and / or data rate. The WTRU 102 may often transmit according to the sustain level or at any time with the transmit power and / or data rate determined by the sustain level.

When the WTRU 102 initiates EU transmission or when the data rate / frequency of the E-DCH transmission is not the same as listed in the channel allocation information (step 312) after the Node-B 104 transmits the channel allocation information. By detecting whether or not, Node-B 104 calculates and reports failed scheduling information reception statistics. This may be based on the received power threshold. The WTRU 102 may also calculate and report failed scheduling information reception statistics by detecting when there is no response to EU channel allocation requests within the time period following the transmission of the channel allocation request (step 312).

If the failed transmission statistics of channel allocation information are higher than a predetermined threshold, the RNC 106 increases the transmission power offset of the scheduling information field on the DL EU signaling channel 110 (step 314). RNC 106 communicates the adjusted power offset to Node-B 104 via Iub / Iur 118.

4 is a flowchart of a step 400 of controlling transmit power of the DL EU signaling channel 110 according to an embodiment of the present invention. After the WTRU 102 is configured for EU operation and receives channel assignment information at step 402, the WTRU 102 sends data via the E-DCH 108 (step 404). Node-B 104 receives and decodes this data. Node-B 104 then sends feedback information (ie, ACK or NACK) to WTRU 102 in accordance with the decoded data (step 406).

The WTRU 102 and / or Node-B 104 calculates MAC-e failure statistics and reports to the RNC 106 to adjust the NACK to ACK power ratio (ie, the ratio of power offsets) (step 408). ). According to one embodiment, the WTRU 102 reports the number of MAC-e failures at the WTRU 102, which is the number of data blocks that were not successfully transmitted. MAC-e failure occurs when the transmission of a data block fails in MAC-e for reasons such as reaching the maximum number of retransmissions or the maximum delay of the data block. Node-B 104 reports the number of MAC-e failures of WTRU 102 at Node-B 104, which is the number of data blocks that were not successfully received at MAC-e of Node-B 104. to be.

Often, a block of data that the WTRU 102 interprets as having been successfully transmitted may not actually be successfully received at Node-B 104, which is incorrectly interpreted as a ACK by the WTRU 102 as an ACK. Because. The RNC 106 reports the number of NACK to ACK interpretation errors of the WTRU 102, as reported by the WTRU 102 in the number of MAC-e failures of the WTRU 102 reported by the Node-B 104. Determine by the number of MAC-e failures of 102.

In addition, the RNC 106 can determine the number of NACK to ACK interpretation errors using the number of radio link control (RLC) recovery requests of E-DCH data for the WTRU 102 at the RNC 106, which request. These may be collected or calculated internally by the RNC 106. The data block that the WTRU 102 interprets as having been successfully transmitted may then have an RLC recovery request for the data due to a NACK to ACK interpretation error. The RNC 106 subtracts the number of NACK to ACK interpretation errors of the WTRU 102 from the number of RLC recovery requests of E-DCH data for the WTRU 102 at the RNC 106 as reported by the WTRU 102. Determined by the number of MAC-e failures of the WTRU 102.

The MAC-e failure statistics of the WTRU 102 at the WTRU 102 are reported to the RNC 106 via RRC procedures, and the MAC-e failure statistics of the WTRU 102 at the Node-B 104 are reported in Iur /. Reported to RNC 106 via Iur 118.

If the likelihood of NACK to ACK interpretation error is higher than a predetermined threshold, the RNC 106 increases the power ratio of the NACK to ACK power offset (step 410). If the power offset is high, the NACK will be delivered more reliably to the WTRU. RNC 106 sends the adjusted power offsets (or power ratio between ACK and NACK) for ACK and NACK to Node-B 104 via Iub / Iur 118, and Node-B 104 Power offsets / ratios are used when setting the transmit power of the EU DL signaling channel.

While the features and components of the present invention are described in the preferred embodiments in specific combinations, each feature or component may be used without other features and components of the preferred embodiments, and other features and components of the present invention and its various It may also be implemented in combination.

A new media access control (MAC) function / entity for media access control (MAC), called Enhanced Uplink (EU), is created at Node-B and WTRU that handles the transmission and reception of E-DCH transmissions. . In order to adequately support the EU, information such as channel assignments, transmission feedback (ie, acknowledgment or non-acknowledge), and other feedback information (such as power control commands or channel quality) may be used in the DL EU. It is effectively and reliably transmitted through the signaling channel.

Power control on the shared DL EU signaling channel is essential to support proper operation of the DL EU signaling channel. Power control reduces interference overall, allowing more efficient use of radio resources.

1 is a block diagram of a wireless communication system according to the present invention.

2 is a signaling diagram between the components of the system of FIG. 1 implementing transmit power control on a DL EU signaling channel according to the present invention.

3 is a flowchart of steps for implementing transmit power control on a DL EU signaling channel according to an embodiment of the present invention.

4 is a flowchart of a step of implementing transmit power control on a DL EU signaling channel according to an embodiment of the present invention.

Claims (20)

A wireless communication system for controlling transmit power of a downlink (DL) enhanced uplink (EU) signaling channel, (a) a radio network controller (RNC); (b) at least one wireless transmit / receive unit (WTRU) for calculating and reporting EU transmission failure statistics and reporting the statistics to the RNC; (c) at least one Node-B that calculates EU transmission failure statistics and reports the statistics to the RNC; (d) at least one DL EU signaling channel in communication with the WTRU and the Node-B, wherein the Node-B sends signals to the WTRU via the DL EU signaling channel, and the RNC communicates with (b); adjusting the transmit power offset of the DL EU signaling channel used when determining the transmit power level of the signals transmitted by the Node-B based on the EU transmit failure statistics reported in (c); The DL EU signaling channel; Wireless communication system comprising a. The method of claim 1, wherein the RNC, In response to the Node-B receiving EU dedicated channel (E-DCH) transmissions from the WTRU, an acknowledgment included in a signal transmitted by the Node-B to the WTRU over the DL EU signaling channel. Adjusting a transmit power offset for at least one of the message or a non-acknowledge (NACK) message, Wireless communication system. The method of claim 2, wherein the EU transmission failure statistics are: Is determined by subtracting the number of EU media access control (MAC-e) failures of the WTRU detected by the WTRU from the number of MAC-e failures of the WTRU detected by the Node-B. Wireless communication system. The WTRU of claim 3, wherein the MAC-e failures occur when the number of retransmissions exceeds a predetermined retransmission limit. Wireless communication system. 4. The method of claim 3, wherein the MAC-e failures of the WTRU occur if EU transmission data expires before being successfully transmitted. Wireless communication system. The method of claim 2, wherein the EU transmission failure statistics are: Is determined by subtracting the number of MAC-e failures of the WTRU detected by the WTRU from the number of radio link control (RLC) recovery requests for the WTRU. Wireless communication system. 3. The system of claim 2 wherein the transmit power for the NACK message is set higher than the transmit power for the ACK message. 6. The system of claim 5 wherein the RNC adjusts a transmit power offset of EU channel assignment information sent by the Node-B in response to a channel assignment request by the WTRU. 9. The method of claim 8, wherein the EU transmission failure statistics are based on the number of times the Node-B has not received any E-DCH transmissions from the WTRU within a predetermined time period after the EU channel allocation information has been transmitted. Which is determined. 10. The system of claim 8 wherein the EU transmission failure statistics are determined based on the number of times the Node-B receives EU transmissions that do not correspond to the EU channel allocation information. The method of claim 8, wherein the EU transmission failure statistics are: Is determined as the number of times the WTRU failed to receive channel allocation information from the Node-B in response to the channel allocation request within a specific time period. Wireless communication system. The system of claim 1, wherein the transmit power level of the DL EU signaling channel for a particular WTRU is determined in terms of transmit power for a DL Dedicated Physical Control Channel (DPCCH) for the particular WTRU. A wireless communication system for controlling transmit power of a downlink (DL) enhanced uplink (EU) signaling channel, (a) a radio network controller (RNC); (b) at least one wireless transmit / receive unit (WTRU) for calculating EU transmission failure statistics and reporting the statistics to the RNC; (c) at least one Node-B; (d) at least one DL EU signaling channel in communication with the WTRU and the Node-B, wherein the Node-B sends signals to the WTRU over the DL EU signaling channel, and the RNC sends the signal to the WTRU by the WTRU. Adjusting the transmit power offset of the DL EU signaling channel used when determining the transmit power level of the signals transmitted by the Node-B based on the EU transmit failure statistics reported to the RNC. EU signaling channel; Wireless communication system comprising a. A wireless communication system for controlling transmit power of a downlink (DL) enhanced uplink (EU) signaling channel, (a) a radio network controller (RNC); (b) at least one wireless transmit / receive unit (WTRU); (c) at least one Node-B that calculates EU transmission failure statistics and reports the statistics to the RNC; (d) at least one DL EU signaling channel in communication with the WTRU and the Node-B, wherein the Node-B sends signals to the WTRU via the DL EU signaling channel and the RNC sends the Node-B to the Node-B. Adjusting a transmit power offset of the DL EU signaling channel used when determining a transmit power level of the signals transmitted by the Node-B based on the EU transmit failure statistics reported by the RNC. The DL EU signaling channel; Wireless communication system comprising a. As a wireless communication system, (a) a wireless transmit / receive unit (WTRU); (b) a downlink (DL) enhanced uplink (EU) signaling channel dedicated to communicating with the WTRU, wherein the power level of the DL EU signaling channel is based on the power level of a current DL dedicated control channel; The DL EU signaling channel; Wireless communication system comprising a. 16. The system of claim 15 wherein the power level of the DL EU signaling channel is based on the current DL dedicated control channel power level and an initial power offset. The method of claim 16, (c) Node-B; (d) a radio network controller (RNC) for adjusting the power offset based on EU transmission failure statistics calculated by at least one of the WTRU and the Node-B and reported to the RNC. As a wireless communication system, (a) a plurality of wireless transmit / receive units (WTRUs); (b) a radio network controller (RNC); (c) a downlink (DL) enhanced uplink (EU) signaling channel shared by the WTRUs, wherein the power level of the DL EU signaling channel is based on a common DL signaling power level initially set by the RNC The DL EU signaling channel; Wireless communication system comprising a. 19. The system of claim 18 wherein the power level of the DL EU signaling channel is based on the common DL signaling power level and a power offset initially set by the RNC. 20. The system of claim 19, wherein the system further comprises a Node-B; Wherein the RNC adjusts the power offset based on EU transmission failure statistics calculated by at least one of the plurality of WTRUs and the Node-B and reported to the RNC.