초록 ▼

Techniques to detect for DTX frames in a "primary" transmission that may be sent in a non-continuous manner using a "secondary" transmission that is sent during periods of no transmission for the primary transmission. The primary and secondary transmissions may be the ones sent on the F-DCCH and Fo

Techniques to detect for DTX frames in a "primary" transmission that may be sent in a non-continuous manner using a "secondary" transmission that is sent during periods of no transmission for the primary transmission. The primary and secondary transmissions may be the ones sent on the F-DCCH and Forward Power Control Subchannel, respectively, in an IS-2000 system. In one method, a determination is first made whether or not a frame received for the primary transmission in a particular frame interval is a good frame (e.g., based on CRC). If the received frame is not a good frame, then a determination is next made whether the received frame is a DTX frame or an erased frame based on a number of metrics determined for the primary and secondary transmissions. The metrics may include symbol error rate of the received frame, secondary transmission (e.g., PC bit) energy, and received frame energy.

대표청구항 ▼

What is claimed is: 1. A method for detecting discontinuous transmission (DTX) frames in a wireless communication system, comprising: ascertaining whether a frame received for a primary transmission in a particular frame interval is a good frame or not a good frame based on an error detection code,

What is claimed is: 1. A method for detecting discontinuous transmission (DTX) frames in a wireless communication system, comprising: ascertaining whether a frame received for a primary transmission in a particular frame interval is a good frame or not a good frame based on an error detection code, a good frame being a correctly decoded frame; if the received frame is a good frame with correctly decoded data, skipping DTX detection for the received frame; and if the received frame is not a good frame, performing DTX detection and determining whether the received frame is a DTX frame or an erased frame based on a plurality of metrics determined for the primary transmission and a secondary transmission received during the particular frame intervals, wherein the plurality of metrics include a symbol error rate (SER) of re-encoded symbols for the received frame, energy of the received frame, and energy of the secondary transmission received during the particular frame interval, and wherein the frame energy is computed as energy of good recovered symbols in the received frame minus energy of bad recovered symbols, wherein the good and bad recovered symbols correspond to no symbol errors and symbol errors, respectively. 2. The method of claim 1, wherein the secondary transmission comprises power control (PC) bits. 3. The method of claim 1, wherein the ascertaining is based on a cyclic redundancy check (CRC) value included in each transmitted frame for the primary transmission. 4. The method of claim 2, wherein the determining includes: determining energy of the PC bits received during the particular frame interval, determining energy of the received frame, and determining SER of re-encoded symbols for the received frame, and wherein the received frame is determined to be a DTX frame or an erased frame based on the SER, the PC bit energy, and the frame energy. 5. The method of claim 4, wherein the determining further includes: computing a combined metric based on the SER, the PC bit energy, and the frame energy, and wherein the received frame is determined to be a DTX frame or an erased frame based on the combined metric. 6. The method of claim 5, wherein the combined metric is expressed as: where Slope is a slope of a threshold line used to separate distribution of erased frames from distribution of DTX frames, and Intercept is an SER value for the threshold line with the ratio of PC bit energy to frame energy set to zero (0.0). 7. The method of claim 6, wherein values for Slope and Intercept are dependent on distributions of erased and DTX frames for a particular operating scenario. 8. The method of claim 1, wherein the determining is further based on a threshold line used to separate distribution of erased frames and distribution of DTX frames that are obtained based on the plurality of metrics. 9. The method of claim 8, wherein the threshold line is selected based on a particular operating scenario for the primary transmission. 10. The method of claim 8, wherein the threshold line is defined based on estimates of at least one metric indicative of current operation conditions. 11. The method of claim 10, wherein the threshold line is dynamically updated based on current estimates of the at least one metric. 12. The method of claim 10, wherein the at least one metric comprises SER of re-encoded symbols, PC bit energy, frame energy, frame status, or a combination thereof. 13. The method of claim 1, further comprising: determining a power control command for adjusting transmit power of the secondary transmission based in part on whether the received frame is determined as a good, erased, or DTX frame. 14. The method of claim 1, wherein the secondary transmission is multiplexed with the primary transmission and sent even during periods of no transmission for the primary transmission. 15. The method of claim 1, wherein the wireless communication system is an IS-2000 or W-CDMA communication system. 16. The method of claim 1, wherein the primary transmission is sent on a Forward Dedicated Channel (F-FCH) or a Forward Dedicated Control Channel (F-DCCH) defined by IS-2000. 17. A method for detecting discontinuous transmission (DTX) frames in a CDMA communication system, comprising: determining whether a received frame for a particular frame interval is a good frame or not a good frame based on a cyclic redundancy check (CRC) value, a good frame being a correctly decoded frame; skipping DTX detection if the received frame is a good frame with correctly decoded data; and performing DTX detection if the received frame is not a good frame, comprising: determining energy of power control (PC) bits received during the particular frame interval, determining energy of the received frame, determining symbol error rate (SER) of re-encoded symbols for the received frame, and determining whether the received frame is a DTX frame or an erased frame based on the SER, the PC bit energy, and the frame energy, wherein the frame energy is computed as energy of good recovered symbols in the received frame minus energy of bad recovered symbols, wherein the good and bad recovered symbols correspond to no symbol errors and symbol errors, respectively. 18. The method of claim 17, wherein the received frame is for a Forward Fundamental Channel (F-FCH) or a Forward Dedicated Control Channel (F-DCCH) defined by IS-2000, and the PC bits are for a Forward Power Control Subchannel that is carried on the F-FCH or F-DCCH. 19. A receiver unit in a wireless communication system, comprising: a decoder operative to determine whether a frame received for a primary transmission in a particular frame interval is a good frame or not a good frame based on an error detection code, a good frame being a correctly decoded frame; a signal quality measurement unit operative to determine energy of the received frame and energy of a secondary transmission received during the particular frame interval; an encoder operative to determine a symbol error rate (SER) of re-encoded symbols for the received frame; and a frame detector operative to skip discontinuous transmission (DTX) detection if the received frame is a good frame with correctly decoded data, to perform DTX detection if the received frame is not a good frame, and for DTX detection, to determine whether the received frame is a DTX frame or an erased frame based on the SER, the frame energy, and the secondary transmission energy, wherein the frame energy is computed as energy of good recovered symbols in the received frame minus energy of bad recovered symbols, wherein the good and bad recovered symbols correspond to no symbol errors and symbol errors, respectively. 20. The receiver unit of claim 19, wherein the secondary transmission comprises power control bits. 21. An apparatus in a wireless communication system, comprising: means for determining whether a frame received for a primary transmission in a particular frame interval is a good frame or not a good frame based on an error detection code, a good frame being a correctly decoded frame; means for skipping discontinuous transmission (DTX) detection if the received frame is a good frame with correctly decoded data; and means for performing DTX detection if the received frame is not a good frame, comprising means for determining whether the received frame is a DTX frame or an erased frame based on a plurality of metrics determined for the primary transmission and a secondary transmission received during the particular frame interval, wherein the frame energy is computed as energy of good recovered symbols in the received frame minus energy of bad recovered symbols, wherein the good and bad recovered symbols correspond to no symbol errors and symbol errors, respectively. 22. The apparatus of claim 21, wherein the means for determining whether the received frame is a DTX frame or an erased frame includes: means for determining energy of PC bits received during the particular frame interval for the secondary transmission, means for determining energy of the received frame, and means for determining SER of re-encoded symbols for the received frame, and wherein the SER, PC bit energy, and frame energy are used to determine whether the received frame is a DTX frame or an erased frame.