The invention is related to the field of short channel detection (SCD), and in particular to an SCD block providing switching between 1× and 2× joint detection (JD).
Experiments have confirmed that a time division synchronous code division multiple access (TD-SCDMA) receiver with a 2× oversampling rate can outperform one with a 1× sampling rate in most fading channels. The gain is particular significant in scenarios with strong neighboring cell interference. However, a 1× receiver can still outperform a 2× receiver in scenarios with AGWN-like channel when close-to optimal timing is available. In addition, 1× oversampling rate of a JD consumes less power. To achieve better performance in both scenarios, a mechanism is needed to switch between 1× and 2× in the inner receiver. The invention addresses this limitation in the prior art.
According to one aspect of the invention, there is provided a TD-SCDMA receiver. The TD-SCDMA receiver includes a joint detection (JD) block receiving a first input signal from a channel estimation block for signal detection. A short channel detection (SCD) block receives the first input signal and detects the presence/absence of an additive Gaussian white noise (AGWN)-like channel based on the first input signal from the channel estimation block and switches the JD block between 1× and 2× oversampling rates by sending to the JD block a second input signal.
According to another aspect of the invention, there is provided a method of performing TD-SCDMA receiver operations. The method includes providing a joint detection (JD) block for receiving a first input signal from a channel estimation block for signal detection. Also, the method includes detecting the presence/absence of an AGWN-like channel based on the first input signal from the channel estimation block using a short channel detection (SCD) block, the SCD block switches the JD block between 1× and 2× oversampling rates by sending to the JD block a second input signal.
According to another aspect of the invention, there is provided a method of performing short channel detection. The method includes obtaining inputs from a channel estimation block and aligning one or more RRC (Root-Raised-Cosine) filter sequences with a desired channel impulse response (CIR) window using the inputs. Also, the method includes building a sequence of active CIR using the one or more RRC filter sequences and calculating the detection metric for each timeslot using the sequence of active CIR. Furthermore, the method includes calculating the decision metric for each subframe and periodically, every M subframes, reading the output of an exponential filter and comparing the filtered decision metric with a pre-defined threshold.
The invention provides a technique for switching between 1× and 2× oversampling rate in a TD-SCDMA receiver. The invention achieves better performance by providing a mechanism needed to switch between 1× and 2× oversampling rate in an inner receiver.
The second signal 20 goes through a channel estimation (CE) block 8 to generate the estimation of the combined CIR, including Tx/Rx filters and air propagation channel. The estimation of CIR 22 is forwarded to a joint detection (JD) block 12 for symbol detection and a short channel detection (SCD) block 10 for switching between 1× and 2× oversampling rate in the JD block 12. The JD block 12 also receives as input the second signal 20. Thereafter, soft detection of symbols 24 is passed to Post JD and bit rate processor (BRP) block 14 for final decoding.
In this case, the channel estimation block 8 runs in a 2× oversampling rate. The JD block 12 sampling rate can switch between 1× and 2×. The SCD block 10 detects the presence/absence of an AGWN-like channel based on inputs from the channel estimation block 8 and switches the JD block 12 between 1× and 2× oversampling rate by sending to the JD block 12 an output signal 26.
The process flow 40 for the SCD block 10 is shown in
To align impulse response (IR) of RRC with a CIR window, one needs to shift IR of RRC so that the peak tap in CIR window and the peak of IR of RRC overlap with each other.
Also, one must build a sequence of active CIR ĥ consisting active windows of both desired UE and non-desired UEs, as shown in step 46, defined as:
where L is the number of active CIR windows.
Correspondingly one can define the sequence of R as:
In other words, R consists of L identical RCshift. The detection metric is calculated for each timeslot, as shown in step 48. This metric is the correlation coefficient between ĥ and R:
where n and j are the indexes for subframe and time slot, respectively.
The alignment was carried only with reference to the desired UE, as shown in
The complexity of this metric can be further reduced. The numerator can be simplified as:
An alternative to metric in (3) and (4) in DMA case is shown as follows. In presence of multiple active windows, one can obtain an individual metric for each active window, then the minimum metric of all these individual metrics is used as the metric for this time slot. In particular,
the metric for kth active window in jth time slot is:
It will be appreciated that all windows use the same RCshift, which is generated with reference to desired UE's peak tap.
Then the metric for the whole timeslot is defined as:
In short, with this alternative SCD can switch to 1× only if all active UE's CE are AWGN-like and they are aligned.
The decision metric is calculated for each subframe as shown in step 50. In DL, there might be more than one time slot in each subframe. The overall decision metric for each subframe is the average of those of all time slots:
Each sub-frame's metric is passed through an exponential filter as shown in step 50. The exponential filter having the following properties:
γave(n)=(1−α)γave(n−1)+αγinst(n)
γave(n): averaged metric after subframe n
γinst(n): instant metric. at subframe n
α: design parameter (1.3)
This exponential filter is a low pass filter, which can “average” the decision metrics over long period of observation.
Periodically, e.g., every M subframes, the output of the exponential filter is read and compared the filtered decision metric with a pre-defined threshold, as shown in step 52. If the metric is greater than the threshold, it indicates the presence of an AGWN-like channel and the SCD block signals the JD block to switch to 1× sampling rate. Otherwise, JD remains running in 2×. The threshold is a design parameter. With theoretical analysis and experiments, 0.94 is a good candidate value.
Although the present invention has been shown and described with respect to several preferred embodiments thereof, various changes, omissions and additions to the form and detail thereof, may be made therein, without departing from the spirit and scope of the invention.
Number | Name | Date | Kind |
---|---|---|---|
7532663 | Lewis | May 2009 | B2 |
7626965 | Cheng | Dec 2009 | B2 |
8311154 | Agrawal et al. | Nov 2012 | B2 |
8315343 | Murai et al. | Nov 2012 | B2 |
20050078640 | Kim et al. | Apr 2005 | A1 |
20120027135 | Sgraja et al. | Feb 2012 | A1 |
Number | Date | Country | |
---|---|---|---|
20120269202 A1 | Oct 2012 | US |