SE523199C2 - Communication signal noise component determining method, involves finding hue of estimated noise based on center of gravity of correlation sequence and passing it through filter when hue is greater than predetermined level - Google Patents

Abstract

The method involves receiving a signal having a noise and estimating the amount of the noise in the signal. The hue of the estimated amount of noise is determined based on the center of gravity of the noise correlation sequence by signal processing unit. The received signal is passed through a whitening filter (80) when the hue of the noise is greater than a predetermined threshold level. Independent claims are also included for the following: (a) a communication apparatus (b) a computer program product directly loadable into an internal memory associated with a processor.

Description

25 30 030929 MDE \\ CURRENT \ DB \ P \ 1874 | n 'oo .nas I. "EriCS5on \ P \ 154_COLORED_INTERFERENCE \ SE \ P18740154_030929_SVENSK_óvarsättninglti1I_P§V.aoc"'. 2 In addition to white noise, there is also colored noise in most electrical systems today. The colored noise can come from many different sources, such as metal-oxide-semiconductor junctions of a field-effect transistor (FET), which produces what is called pink noise or flicker noise. As will be described below, interference between co-channels and adjacent channels of a communication system will also act as sources of colored noise.

The colored noise is characterized by an uneven distribution of the noise effect over the entire frequency spectrum. For example, pink noise has the same noise power distribution for each octave, so that the noise power between 10 kHz and 20 kHz is the same as between 10 kHz and 200 kHz. Many other colored noise forms are defined and described in the literature, however, all of these exhibit the basic characteristics of an uneven noise power distribution.

In wireless communication systems, the background noise of the communication channel is usually white. However, the performance of these systems is not only limited by the background noise, but also by the interference emanating from other users of the system. As is well known in the art, the multiple access scheme defines how different simultaneous communications between different mobile stations, which are located in different cells, share the same radio spectrum. In the case of GSM, a multiple access system has been adopted in the form of a mixture of FDMA (Frequency Division Multiple Access) and TDMA (Time Division Multiple Access).

More specifically, in GSM 124 carrier frequencies, each having a bandwidth of 200 kHz, form a 25-MHz frequency band using an FDMA system. Each of the 124 carrier frequencies is then divided over time using a TDMA system. This system divides the radio channel, with a 200 kHz bandwidth, into eight signal bursts. En 10 15 20 25 30 35 030929 MDE \\ cuRRaN'r \ oß \ L = - \ 1e14. . . .- -n - u- ',,' sricssorn1> \ 1s4_coLoRzo_nrrsarsRsNcs \ smP1av4o1s4_o3o929_svENsK_översaccningjril1'_Pr! v. 3 single users are then assigned a signal part for communication.

In narrowband TDMA systems, such as GSM, there are usually two types of interference. Users with the same carrier cause co-channel interference, while users with nearby carriers cause nearby channel interference.

As mentioned above, noise due to co-channel and adjacent channel interference appears as a colored spectrum with a non-uniform distribution of the noise effect. In addition, a receiver filter, which is usually located at the receiver input and is narrower than the Nyquist bandwidth, can also make the background noise appear colored.

The colored noise significantly degrades the performance of a "most likely sequence sequencer" (MLSE, according to the English term "Most Likelihood Sequence Estimate equalizer") present in the receiver, and is optimal only assuming that the present (WGAN, English term "White Gaussian Additive Noise"). ”). the noise is white Gaussian additive noise according to it To combat performance degradation due to colored noise, a "whitening filter" can be inserted before the equalizer.

In addition, a non-distorted channel estimate ("BLUE", according to the English term "Best Linear Unbiased Estimation") may also be necessary. Both the setting of the whitening filter and the non-distorted channel estimate require knowledge of the noise properties, which can be obtained by an initial estimate of the autocorrelation of the noise as well as knowledge of the signal information (eg from the training sequence of GSM systems).

As mentioned above, the whitening filter and the non-distorted channel estimate significantly improve the performance of the equalizer when the noise is very colored (ie the color tone of the noise is very strong), such as when a very strong nearby channel interference occurs. However, when the noise is close to white, the whitening filter and the 523 199 lO 15 20 25 30 35 c ø | v oo noun n. n »un n-" Q f .. o vv 0 z 'zv un nu:',,, nu vv: z, 'f. nu' .or: nu n. oo. a oc: ' ° ', g flfi I:. N H. | A | nu v. 030929 MDE \\ cuRRsNT \ DB \ P \ 1s74; gg', ° .. aricssonwus4_co1.oxsn_mrsnrsazucmsmmeno1s4_oao92gsvx-: Nsrgöversäcrnedaqgna a deterioration in performance, which in some circumstances can be significant, such as in hilly landscapes.

This is because the estimation of the noise property may be deficient with a limited length of the training sequence. At a certain noise tone level, the gain from whitening will be offset by the deterioration due to the deficiency of the noise estimate. Furthermore, the use of whitening filters as well as non-distorted channel estimation will increase the counting load placed on signal processing units of the system.

WO-0139448 A1 describes a system for whitening a signal interference of a communication signal by using a filter, the coefficients of which are adaptively established by using known signal information of each signal part of the received signal. In an embodiment described in WO-0139448 A1, the received signal is processed by a whitening filter having M + 1 wherein M is a certain integer. the whitening filter is based on a linear predictor of sockets, the coefficients of the order M for the signal interference. Alternatively, the coefficients may be based on the autocorrelation of the signal interference. The method of performing the whitening of the signal places high demands on the process which performs the calculation, even if no or very little colored noise is present in the signal, since the whitening process is carried out independently of the color tone of the present noise.

US-5031195 discloses an adaptive modem receiver which comprises an adaptive white matched filter (WMF, according to the English term "Whitened-Matched Filter"). The WMF includes an adaptive linear equalizer and an adaptive linear predictor. The coefficients of the predictor are updated so that the noise at the input of a subsequent sequence decoder turns white regardless of whether the added noise from the passage through the communication channel 10 15 20 25 30 35 u - n | nu 030929 MDE \\ CURRr-: N1 '\ DB \ P \ 1s74. . . u. . . . . - __ ancssonwu54_coLoREo_1NTaRrßRENcE \ ss \ P18740154_o3o929_svENsK_översaccninqgil112411.dec "" "5 is correlated or not. No means are provided to reduce the calculation load even if the noise is white or very little.

US 5283811 discloses a decision feedback equalizer which improves the performance of a receiver when the transmitted signal is subjected to multipath propagation, which causes delay spread and inter-symbol interference as a result. In areas where the delay spread due to multipath propagation is low (ie less than 1/3 of the symbol time), the equalizer can be disconnected from the circuit. However, no measures are described in US 5283811 for improving the performance of the receiver based on the coloration of the present noise caused, for example, by nearby channel interference.

Summary of the Invention The present invention seeks to provide a method for improving the performance of a communication device that receives a signal which is exposed to noise resulting from, for example, adjacent channel interference and co-channel interference.

This object is achieved by means of a method for receiving a communication signal r (t) exposed to noise n (t) over a communication channel comprising the steps of 1) receiving (100) the communication signal r (t) comprising the noise n (t), 2) estimating (103) the noise power n (t) of the communication signal r (t), 3) determining (105) the color tone of the estimated noise n (t), the received communication signal r (t) passing through a whitening filter, if the noise n ( t) hue is higher than a predetermined threshold level.

According to a preferred embodiment, the method is performed by a communication apparatus, which comprises: circuit devices (30, 40, 50) for receiving a 523 199 10 15 20 25 30 35 n n u IH: "u - ~ ':'. 2. 5 2 3 1 9 9 ~ '' ° 030929 Mm: \\ cuRzzr-: N'r \ oB \ P \ 1a14 * "" '' '' ', ov ro uo' sncssonun1s4_co1.oREDJNTI-: Rrr-: Rzucsnssuuav401s4_o3o929_svaNsK_öveL-sannin'g_c111_'s-Rv'.doc "" 6 communication signal r (t) which is exposed to noise n (t) via a communication channel and a signal processing unit (60), which is adapted to: (1) use t) of the communication signal r (t), 2) determining (105) the color tone of the estimated noise n (t), and switching on (107) a whitening filter (80), if the color tone of the noise n (t) is higher than a predetermined threshold level .

Additional objects, features and advantages of the present invention will become more apparent from the following detailed description of a preferred embodiment.

Brief Description of the Drawings A preferred embodiment of the present invention will now be described with reference to the accompanying drawings, in which: Figure 1 is a schematic block diagram illustrating the various machining blocks according to a preferred embodiment, Figure 2a is a schematic graph illustrating the result. of the autocorrelation calculation of an information sequence r (m), Figure 2b is a schematic graph illustrating the results of the autocorrelation calculation with white noise, Figure 2c is a schematic graph illustrating the results of the calculation of the autocorrelation of colored noise, and Figure 3 is a schematic flow diagram showing illustrates the steps for determining a color noise tone of a signal according to a preferred embodiment.

Detailed Description of a Preferred Embodiment Figure 1 provides an overview of a receiver of a communication system according to a preferred embodiment of the present invention. 10 15 20 25 30 35 o 523 199 ësz fi ffv fi a fi üßfíëïf 030929 Moa \\ cuRRaN'r \ DB \ P \ 1a74; ; ; °, '' ,, ".. '' .. 'zncssernrustcoronzognrnarsmaucs \ sz \ visums4_ososzgsvznsrgsvefsätuning; ing-Rv.dos 7 the function of the invention and the information can just as well be transmitted by means of light, wired or with another suitable communication medium, but for the sake of simplicity, only communication by means of radio waves is described in this text.

Before signal s (t) is transmitted from the transmitter 20 in Figure 1, the signal s (t) is modulated with a high frequency down link carrier, which in the case of GSM communication is in the range between 935-960 MHz. The output of the transmitter is thus an RF signal (ie the carrier is envelope modulated with s (t)), which is suitable for the transmission.

Regardless of which communication medium is selected for the transmission of the information signal s (t), the signal s (t) will be changed in that interference n (t), which is related to the characteristics of the channel 10, will be introduced during the transmission via the communication channel 10 itself. The disturbances arise, as mentioned above, from many different sources, of which co-channel interference and adjacent channel inference have a significant proportion.

The HF signal is received at the HF circuit device 30, which in a preferred embodiment operates according to the homodyn principle, and the received information signal r (t) is consequently extracted from the received HF signal by mixing the received HF signal with a signal from a local oscillator 31. As is the case with the above-mentioned signal modulation, the signal demodulation according to the homodyne or heterodyne principle is well known in the art and can be readily found in the literature.

However, all other suitable demodulation principles are possible within the scope of the invention. 10 15 20 25 30 ecco av. 030929 MDE \\ CURRENT \ DB \ P \ 1874,. . .. _ s: icssonwu54goronanun-rsnvzkaucrnss \ P1av40154_oao92e_svsusr <_övefsactninå_nifljxvfdoc '8 a time-discrete digital signal r (m). The sampled and converted signal r (m) is received, after filtering through a low pass filter 50, by a signal processing unit 60, which in a preferred embodiment is in the form of a DSP (Digital Signal Processor), which performs the steps described below by executing program code as stored in a memory 61.

However, the signal processing unit can also be designed in the form of, for example, an FPGA (Field Programmable Gate Array) or an ASIC (Application Specific Integrated Circuit).

The signal processing unit performs a first initial channel estimate after a burst synchronization based on known signal information (ie the training sequence of GSM / EDGE) present in the received signal r (m). The received signal r (m) is compared with the expected symbol sequence to determine the noise sample n (m) according to the formula: Ms-1 "k = rk" Zh: 5k- | (1) fw The embedded training sequences usually have a short length. This means that it is very difficult to determine the noise properties by analyzing the sequence in the time domain. In this case, the calculation of the n (t) autocorrelation of the noise is a powerful tool for obtaining information regarding the noise spectrum. nunnan 0 10 15 20 25 30 va 030929 Mm: \\ cuRxaNr \ oB \ P \ xsv4 E "š",, '.. “' .. '' 'aricssormvu54ponoasugufranranzncrnss \ 1> 1s14o1s4_o3o929_sv |: annx_c> = 9 In general, the estimate of the autocorrelation of the noise (assume a zero mean value) is calculated from the estimated noise samples according to the formula: 1 Ns-kl P / Fj: šnfnm. (2) wherein Ns is the number of estimated noise samples and wherein () * indicates the complex conjugate. The autocorrelation of noise is generally a complex, conjugate-symmetric sequence, so that the negatively indexed elements can be obtained from the above equation ß - ,, = p * - pg is always a real element. positive indexed equivalent, According to Figure 2a illustrates the result of the autocorrelation calculation with an information sequence r (m). As shown in Figure 2a, the result of the autocorrelation is a vector, which in this case is presented as a graph with its center on the Y-axis (ie zero delay), and which then decreases to zero as the delay increases (or when the lead increases if future signal values are known). Consequently, the information sequence exhibits a high degree of autocorrelation between adjacent and adjacent samples.

If no information signal was present, ie. the signal includes only the noise n (m), as shown in Figure 2b, the autocorrelation is almost zero for each delay (except for the delay = 0, which is always 1 by definition) and without any dominant peaks found in Figure 2a.

Figure 2c illustrates an autocorrelation of the noise n (in the case that the noise is not white and uniformly distributed across the spectrum but rather colored in that the noise effect is higher on some parts of the spectrum. This occurs, for example, in channels with strongly adjacent channel interference. in Figure 2c, it shows vo .pn,, =. en u '.no I' '' '"o: o * PU: vn' II '', 'Ä u. u» I': ". a. au . :: ...: nn-:. o | .unn,. u 0 10 15 20 25 30 'c nu nu II',. n. u ~ II "':,' ° .. n AI I z; nu I. 0 I 'Q: 1. uueo' ÉÜ. 1 .1 II. u n. n »-: 1 fl.: ': n -. no" - acl' _ .I,. nu ß '030929 HDE \\ CURRENT \ DB \ P \ 1874 go | a EriCSs0n \ P \ 154_COLORED_INTERFERENCE \ SB \ P18740154_030929_ENGLISH_translation_to_PRV.doc the noise (ie a higher hue value) will result in an output f rob the autocorrelation calculation, which has higher values for delays other than zero than a faintly colored signal interference.

The signal processing unit 60 then determines the center of gravity of the autocorrelation function according to the formula: Ns-1 2 (k + DIPJ m Zïßär k = 0 Note that the formula, in a preferred embodiment, uses the term k + 1 instead of k at the numerator to maintain the weight of the first and most However, other functions can also be used to determine the center of gravity of a function.

The more strongly colored the noise, the higher the values will be obtained as a result of the calculation of the center of gravity 0. This is due to the fact that a noise signal with a strong staining will result in an autocorrelation with high values for delays other than zero, and that the center of gravity is only calculated for one side of the autocorrelation, i.e. only autocorrelation values to the right of the Y-axis are taken into account.

The color tone of the noise can thus be determined by a single variable 0. A threshold value can then be set in accordance with N and s to switch on / off the whitening filter / the non-distorted estimate. In practice, it occurs, for example, for GSM / EDGE, with a training sequence of 26 10 15 20 25 30 35 1 I 030929 MDE \\ CURRENT \ DB \ P \ 1B74: 5, PRV. doc ~ EriCsS0n \ P \ 154_COLORED_INTERFERENCE \ SE \ P18740154_O30929_ENGLISH_translate_to_11 symbols of a normal burst, that a threshold value can be set experimentally to: 1 + s GT = Note that the threshold value in this case is not proper - 523 199 If G is less than 05, the noise is considered white, and the whitening filter and the non-distorted estimate (BLUE) are bypassed by the colored interference identification block 100. Instead, a much simpler least squares estimate 70 can be used to estimate the channel impulse response. This will reduce the need for computing power of the signal processing unit 60, which in itself makes it possible to reduce the clock frequency of the signal processing unit 60 by using, for example, PLL techniques. As is well known, the reduction of the clock frequency of an electronic system also reduces the energy consumption of the system. With a certain battery capacity, the system will thus remain functional for a longer period of time. On the other hand, if the threshold value G is greater than 03, the noise is not white, whereby the non-distorted estimate and the whitening filter 80 are switched on before the equalizer 90.

Figure 3 illustrates a flow chart for determining the color tone of the noise n (m). The procedure begins at step 100 with the reception of the baseband signal corresponding to the training sequence. As mentioned above, it is understood in this connection that the information signal r (t) is usually obtained by demodulating an RF signal. Regardless of which transmission procedures may have preceded the reception (i.e., all HF modulation-demodulation procedures typically performed when a signal is transmitted), the received baseband signal includes both the expected MDE \ \ CURRENT \ DB \ P \ 1874 o 0 'Ericsson \ P \ 1 54__COLORED_INTERFERENCE \ SE \ P1B740154_030929_SVENSK_översättning_till_PRV. doc 12 - «.- G '' 'u the training sequence s (t) through the propagation channel and noise n (t).

Before further processing, the signal is converted to a time-discrete digital signal r (m) with an analog-to-digital converter (ADC) of step 101. The ADC is usually of the oversampling type (ie the signal is sampled with more than twice the highest frequency component of the signal). ), however, it can also be of the Nyqvist type (ie the signal is sampled with twice the highest frequency component of the signal).

The A / D converted signal r (m) is low pass filtered before being transmitted to the signal processing unit 60, where a first estimation of the noise power n (m) is performed at step 103. As described above, this is possible thanks to a known signal sequence (ie the training sequence at GSM), which is present at the received signal r (m). Since the training sequence will be distorted by the channel properties (ie noise is applied, for example multiple propagation paths interference and additive interference), it is possible to determine the noise of the signal by comparing the received signal r (m) with the known training sequence.

An autocorrelation of the estimated noise signal n (m) is calculated in step 104. The autocorrelation will reveal the frequency characteristics of the noise signal even if the signal has a very short length. Most digital signal processors (DSPs) available today are adapted to perform autocorrelation calculations efficiently, which means that the autocorrelation calculation is not a significant load in terms of processing.

At step 105, the center of gravity of the autocorrelated noise is calculated according to equation 3. If the color tone of the noise n (m) is low, the center of gravity will be located close to the delay = 0 because the energy of delays <> 0 is very low, as shown in Figure 2b. However, if the hue is 10 15 20 25 30 35 | n 0 u I F.,. «- uu. 0,.

~ '' 'N 030929 MDE \\ cuRsu-: N'r \ Ds \ P \ 1s74 5 2 3 1 9 9 Ericss0n \ P \ 154_COLORED_1NTERFERENCE \ SE \ P18740154_030929_SVENSK_översätttning: ëill_PRV kanalginterna 13 pushed further away from the Y-axis, as shown in Figure 2c.

The signal processing unit 60 determines at step 106 whether the center of gravity o'er is above a predetermined threshold UT, which can be based on both empirical and mathematical grounds.

If the center of gravity is above the threshold level GT, the signal processing unit 60 activates the whitening filter 80 and the non-distorted channel estimate of step 107, through the colored interference identification block 100.

It will be appreciated that the whitening filter / non-distorted channel estimate 80 may be performed by the signal processing unit 60 itself, by a separate DSP, by a fixed logic circuit such as an FPGA (Field Programmable Gate Array) or by an ASIC (Application Specific Integrated Circuit). . The whitening filter will then provide a less colored signal to the equalizer (or demodulator) 90, which in turn will increase the equalizer performance as the equalizer assumes that the interference introduced by the channel is white.

However, if the center of gravity 0 is below the threshold value GT, the whitening filter will not be activated because the noise is considered white. Using the whitening filter on a signal involving white noise will not only increase the computational load described above but will in most cases also reduce the efficiency of the decoding procedure of the equalizer 90. Instead, the whitening filter and the non-distorted channel estimate are bypassed.

The present invention has been described above with reference to a preferred embodiment. However, embodiments other than those described herein are possible within the scope of the invention, which is defined by the appended independent claims.

Claims (17)

10 15 20 25 30 35 9 znrygf 93 "?.. ... ',....: H; 030929 nu: s = \ 1 = \ 1a74 sricssonun1s4_coL.onsn_zmxznømnsuclnsnuus7401s4_o3o92s_åiausšzïhveïßaccünšj V A method of receiving a communication signal r (t) exposed to noise n (t) over a communication channel, comprising the steps of: receiving (100) the communication signal r (t) comprising the noise n (t), estimating (103) the amount of noise n (t) of the communication signal r (t), and determining (105) the color tone of the estimated amount of noise n (t), the received communication signal r (t) being passed through a whitening filter if the color tone of the noise n (t) is greater than a predetermined threshold level. The method of claim 1, wherein said noise n (t) is estimated (103) by comparing the received signal r (t) with known signal information. A method according to claim 1 or 2, wherein the frequency characteristics of the noise n (t) are determined (104) by performing an autocorrelation with the noise n (t). The method of claim 3, wherein the color tone of the noise n (t) is determined (105) by determining the center of gravity 0 'of the autocorrelation sequence of the noise. The method of claim 4, wherein the color tone of the noise is determined by a single variable. A method according to any one of claims 4 or 5, wherein the color tone of the noise is determined according to the formula: 10 15 20 25 30 5 2 5 1 9 9 -. . . . . . . . - - .. ° 'n I ".o fi'" SK_6frersàttning_til1_PRV.doc 030929 MDE G: \ P \ 1874 EriCSsOn \ P \ IS4_COLORED_INTERPERENCE \ SE \ P1B7401S4_O3092§_SVlN 15 Ns -1 2 (k + 1) a - = ---- Ns-l ZIPIZ k = 0 The method of claim 1, wherein the threshold level engages a non-distorted channel estimate. 8.; Communication apparatus comprising: receiving circuit devices (30, 40, 50) for receiving a communication signal r (t) exposed to noise n (t) over a communication channel; a signal processing unit (60) adapted to: estimate (103) the amount of noise n (t) of the communication signal r (t); determining (105) the hue of the estimated amount of noise n (t); and turn on (107) the n (t) threshold level of the noise. (80) hue is greater than a predetermined whitening filter The apparatus of claim 8, wherein the signal processing unit (60) is adapted to estimate (103) the noise n (t) by comparing the received signal r (t) with known signal information. Apparatus according to claim 8 or 9, wherein the signal processing unit (60) (104) autocorrelates the noise n (t) with the noise n (t). is adapted to determine frequency properties by performing a 10 15 20 25 30 v s I I ",, - a Q n I" 523 199 š. '. = š'. '= "-". .. -; .. -_-__ '. 030929 Mus c .- \ 1> \ 1av4 Ericsson \ P \ 1s4_cor.onzn_xNTr-: RFr-: Rsncznsauns140154313o92LSVWSQß-fersiuuninglr.illlvnv.dec 16 11. ll. The apparatus of claim 10, wherein the signal processing unit (60) is adapted to determine the color tone (105) of the noise (105) by determining the center of gravity G of the autocorrelation sequence of the noise. The apparatus of claim 11, wherein the signal processing unit (60) is adapted to determine the color tone of the noise with a single variable. Apparatus according to any one of claims 11 or 12, wherein the signal processing unit (60) is adapted to determine the color tone of the noise according to the formula: Ns-1 2 2 (k + 1) | p | 0 = 2 lßl k = 0 The apparatus of claim 8, wherein the signal processing unit (60) is adapted to engage a non-distorted channel estimate if the color tone of the noise n (t) is higher than a predetermined threshold level. The apparatus of any of claims 8 to 14, wherein the signal processing unit (60) is a digital signal processor (DSP). A computer program product which can be directly fed into an internal memory (61) belonging to a processor (60), the processor being operatively connected to 50) for receiving a communication signal r (t) exposed to noise n (t) for receiving circuit devices (30). , 40, over a communication channel, including program code 523 19. ° 'nv I' oaoszs Mos c = \ 1> \ 1a74 Erica: on \ Pusgcomnsnjmsn fl snrancs \ sz \ P1s74u1s4_o3o fi šjvärisgbåreraåccninicillln (t); determining (105) the color tone of the estimated amount of noise n (t), and switching on (107) a whitening filter (80) if the color tone of the noise n (t) is greater than a predetermined threshold level when executed by the processor. A computer program product as defined in claim 16, 10 formed on a computer readable means. u '. n,. nnnn fl :. h '' .nl ": °" 21- "'- .:" "'. É ~~. -I g u. 0 ._,