SE412826B - PLANT FOR THE CONVERSION OF A OLYMPIC SAMPLED SIGNAL WITH SHORT-TERM SPECTRUM TO A SIMULAR SAMPLED SIGNAL - Google Patents

Description

7 800l + 88 - 3 a with eight given samples. It is possible to find such coefficients with the help of which one can extrapolate omitted samples correctly for signals with frequencies within a maximum of two of the four compartments that emerge during the discrete Fourier transformation of eight known samples. Through the transformation, the two largest compartments emerge the signal amplitudes are present, and then corresponding weight coefficients are applied for correct extrapolation of signals with frequencies within these two compartments. With four compartments there are six possible combinations, and the weight coefficients for these six combinations are determined in advance and stored in a coefficient memory. The coefficients multiplied in turn by each of the eight samples and the sum gives amp- lltuden on the next subsequent omitted samples. Through repeated procedure four times, the next four omitted samples can be extrapolated, while the the next four omitted samples in a corresponding manner can be successively extrapolated race in the other direction from the next group of eight known samples. Alternatively, all take the samples extrapolated in one direction starting from the same group of eight given. sample.

The present invention constitutes a further development of those in the claim in the introduction. the indicated part of the invention and what is particularly characteristic of the invention of the characterizing part of claim 1.

Advantageous embodiments of the plant specified in claim 1 have specified in the subclaims.

In order that the invention may be better understood, the same will be described in more detail in the following with reference to the accompanying drawing figures.

Fig. 1 is a block diagram of a previously proposed device.

Fig. 2 is a block diagram of a modification also previously proposed. cation of the device shown in Fig. 1.

Fig. 3 is a block diagram of a plant according to the present the finding.

Fig. Ha shows the appearance of transferred samples with gaps between groups of transferred samples and Fig. Bb shows a device which is suitable for a signal such as that shown in Fig. ka.

Fig. 5 shows a time-frequency converter.

Fig. 6 shows a variant of the device shown in Fig. 5.

The previously proposed and indicated by the block diagram in Fig. 1 The device comprises a device with extrapolation of omitted samples in one and the same direction from a group of eight samples. The device according to Fig. 1 comprises a delay chain F1 - F8 with eight series-connected delay elements F1, F2 .... F8, a multiplication unit M1 with eight multiplication circuit arraysLä (k), OÅ; 3 (k) .... c (_1 \ (k), 0 (1 (k) ..... G (¿(k) connected on the input side to connection points in the delay chain and on the output side to a common summing circuit S1, and a frequency analyzer FA1 connected on the input side to the same eight connection points in the delay chain F1 - F8 as the multiplication unit M1 and on the output side of 7800488-3 four connections on a logic unit L01 arranged to compare four signals from the frequency analyzer FAI with respect to amplitude and to output a control signal lst the tlll multiplication circuitsG1¿h (k) ... n (h (k) depending on the result of the made the comparison and thereby activate one of 6 multiplication coefficient sentences stored in each of the multiplication circuit numbers K: h (k). . . . ..CKü (k).

The coefficients are so adapted that the transfer function of the set m.a.p. extrapolated samples are real and close to 1 within the frequency range of the equivalent rande two compartments. (For speech signals, the first compartment does not have to start at 0 Hz because in telephony the range 0 - 300 Hz lacks interest. In the same way. .t_ there is for the last compartment an area close to l / 2T Hz, within which signal is not transmitted,) In addition, the input and output terminals of the delay chain are the input and output terminals of the device. gait clamps I resp. U. The frequency analyzer FA1 is arranged to perform the four mathematical operations: Z _ Ü I sflë§ == ~ i Il 'i 2. s; ëka fi n-qfy; zgj fi gk fl- »lå- (lu-qqsš fl ä k = = u '1- i "_ * - w šleilta-: ßä * <- «-«. f »~: -% l an ... u - 2 'f a. å, ¿., {qt; -q,).; ._ 1¿q .- gt fi dpidatl-qfl-g-ê; fl iurkgi-o where y1 - yh indicates the signal strength in four different frequency bins in the frequency range 0 - = H l / 2T Hz and where xk with -b = 55k: Eàü are the eight signals from the delay chain .i Fi - FB, which are multiplied by the coefficients given by the formulas above and y1 - yh are the four signals to the logic unit LO1. The S1 output of the summing circuit is over a contact K connected to one end of the delay chain F1 - F8 (input) at times when sampler sakhans in the non-uniformly sampled signal.

In the general case of Nst delay elements resp. multiplication circuits becomes the system of the mathematical operations: Ä 'TQÛOÄSS - 3 .N fi _ 2 I ”A g _ _ [ha (145 -l- åïinæI fl kl-qfytïqxjšínš] then-VKÉO all »lá if ä 'get even' and å “ä 'Z .a xosk-'Åïq-el- xx: k-i-P- u 'u-: ëší td š fl åkní then? do it! -Érllludclm (H .. I å - '”°" "" “” 1 'and the number of multiplication coefficient sets k .. fßl fl / RJÅ However, one may have more or fewer sets than this expression indicates. based on the design of the log unit L01. Then you can e.g. in addition, the coefficient settings for correct extrapolation of signals with frequencies in only one frequency vensfack. Regarding the choice of N, this number should be in the range 6 - 16. At an N-value less than 6, poor frequency resolution is obtained, and at an N-value those larger than 16, there will probably be many pulses to calculate in succession in the gaps between r groups of samples.

The similarly previously proposed device according to Fig. 2 comprises in addition units F1 - F8, FA1, L01, M1 and K acc. Fig. 1 also shows a delay chain F21 - F35, a multiplication unit M2, a frequency analyzer FA2 and a logic unit L02. These later units together constitute a conversion device of in principle the same kind as the device according to Fig. 1. The delay chain F21 - F35 comprises five tons of delay element and has its output connected to the delay chain F1 -.

F8 input. A switching circuit 0 is arranged to switch the connections between the pre- ~ .the delay chain F21 - F35 and the frequency analyzer FA2 resp. the multiplication unit M2 two steps (two sample positions) towards the common connection of the delay chains point for each sample within a group of samples previously missing in the different mlgt sampled the signal. This results in the conversion device F1 - F8, FA1, L01, M1, K to be responsible for generating a group of samples and the conversion device F21 - F35, FA2, L02, M2, 0 to be responsible for generating an equal group of samples, so that the originally non-uniformly sampled signal becomes uniformly sampled.

In the general case of N st. samples in each group and M excluded samples between the groups, the number of delay elements in the delay chain F21 - F35 equal to N + M - 1, and the number of delay elements in the delay chain F1 - F8 still equal to N..

The present invention is based on the basic organs set forth in in connection with the description of the application shown in Fig. 1 and relates to a plant where, using means shown in Fig. 1, a group of means on a transmitter side can be connected to a group of means on a receiving side via a transmission line. gt: a 7800li88-3 In this facility according to the present invention, have means such as corresponds to those shown in Fig. 1 in the same way. At the facility according to according to the invention, the multiplication unit denoted by M1 together with one of the elements F1 ..... F8 consisting of delay chain arranged on it with R designated the receiver side while the frequency analyzer FA1 and the logic unit ten L0i is present on the transmitter side designated T. The transmitter side is equipped with an input l and together with the said frequency analyzer Fal have used an additional delay chain has been arranged consisting of the n elements Fa + 1 .......... Fa + n (n eg = N). From the last of the latter delay chain element Fa + n, the intended sample signal passes via a switch denoted by 01 omitting certain samples and via the transmission line included in the transmission line. conductor L1 to the element F1 in the delay chain F1 .... F8, which is copper add to the multiplication unit Mi in the receiver side denoted by R and is provided from the plant via the connection connected to the delay element F8 ningen U.

From the logic unit L0i on the transmitter field T, a control signal lst passes through it second l the transmission line input conductor L2 to the multiplier unit Mi on the receiving field R.

In the same way as with the previously proposed device shown in Fig. 1, there is on the receiver side R a contact K for the same purpose as previously used given. I _ Regarding the working method, reference is made to the previous description of the device shown in Fig. 1.

At the plant shown in Fig. 3, it may be desirable that in cows between groups of transmitted samples have scattered samples, which are transmitted. Fig. Äa shows examples of the appearance of such signals with sample groups SG. Hereby have the reception side R is modified so that the output of the contact K is connected to the delay chain F1 ..... F8 a bit into this, for example after two delays and thus between the delay elements F2 and F3, as shown in flg. Open. In this case, in the case of obtaining excluded samples, even the nearest extra transferred sample is multiplied by the multiplication coefficient in the the application unit.

It is also possible to combine the devices described above. devices for transmitting speech signal samples in the frequency domain of instead of in the time domain, Fig. 5 shows the time-frequency converter TFCI (between its two chains F of delay elements) which are added at the end of the transmitter side immediately before the transmission, as well as the frequency-time converter FTC1 (between its jor F of delay elements). The advantage of using samples with samples in the frequency domain instead of in the time domain at the actual transmission is that these signals are less sensitive to interference. In addition, known methods for additional more data reduction of such signals is applied. 7800488-3 Fig. 6 shows a variant in the form of a further development of the one in "Fi§f" 5 "_m" showed the device. Here is a time-frequency converter TFC2 and a_frequency- time converter FTC2 with its resp. delay chains F. Fig. 6 shows a switch lare 02 and this excludes in the transmitted signal of samples in the frequency domain certain samples (as many as are excluded from the signal in the time domain at the switch) 01 in Fig. 3). The frequency-time converter FTC2 has a special shape. (See an essay by T. Fjällbrant: "A method for the derivation of weighting coefficients for extra- polation using a Discrete Fourier Transform with prescribed conditions in both the time and frequency domains ". Proc. of the Florence Conference on Digital Signal Processing, l975, p. 289 - 295.) When converting signal samples in the time domain to signal sample in the frequency domain acc. known methodology, the number of samples in the number of samples in the time domain independent of the amplitude of the sample l the time domain (although some samples have been excluded by the switch Ui and thus received the amplltud value is kept for that reason no fewer samples in the frequency domain).

Despite the fact that the switch 02 excludes as many samples as excluded in the signal of samples in the time domain by the switch 01, it is still possible to regenerate the sample in the time domain of the frequency-time converter FTC2 on the recipient side performs mathematical operations according to the previous description and FTC2 thus has conditions in both time and frequency domains. The advantage of this order is of course that the amount of data that needs to be transferred is significantly reduced since some frequency samples are deleted.

Claims (3)

7 7800488 -3 Patent claims A plant for converting a non-uniformly sampled signal with a short-term spectrum into a uniformly sampled signal using a multiplication unit (Mi) with N multiplication circuits (C>! _ h (k)... .. ° <¿( k)) connected on the input side to connection points in a delay chain (Fl ... F8) and on the output side to a common summing circuit (Sl), a frequency analyzer (FAI) connected to N / 2 connections on a logic unit (LOI) arranged to compare N / 2 signals from the frequency analyzer (FAI) with respect to amplitude and outputting an oxygen signal (lst) to the multiplication circuits depending on the result of the comparison made, thereby activating one of a plurality of multiplication coefficient sets stored in the multiplication circuits, whereby performing frequency analysis de N / 2 matematiska operationserna: _1, _ _ _ 2. _ _ ”_ 1 gå-flßlç fi føiglk-Pülf) (l-ßf -t Sin dill-kan Du. lsïfåßr Njömf» L a '' ä - f, - 2 'fi šl - .tu i ßf [,, f »1lf °°“ l' ° * '% ll + 2ßš "° '“ l' °° fi] aa »Is t-.sïštsf fl aaæa where xk with -N / 2: 5 k: §N / 2 are the N signals from the delay chain (F1-F8) and yI .... yN / 2 are the N / 2 signals to the logic unit (L01), and the output of the summing circuit (S1) is connected to one end of the delay chain (F1 ~ F8) at times when samples are missing in the non-uniformly sampled signal, characterized that the frequency analyzer (FAI) together with the logic unit (L01) is arranged on a single transmitter side, the frequency analyzer (FA1) being connected to a further delay chain present on said transmitter side (Fä + 1 .... Fa + n) and said transmitter side being connected with a group of means arranged on a receiver side, which comprises said multiplication unit (M1) together with the associated delay chain (F1 ..... F8) via a transmission line, which comprises a first conductor (Li) for transmitting speech signal samples from the output of the said additional delay chain (Fa + 1 _........ Fa + nl and a second conductor (L2) for transmitting n said control signal (lst) from said logic unit (L01) to said multiplication unit (M1). Plant according to claim 1, characterized in that the said plurality of multiplication coefficient sets amounts to ill)) 7 -, _ *. u 'àägjt) ßalsqsa: a undan '04 _ gzl .Rh- N Hilal »7800488-3 8 3. Plant fi ng acc. claim 1 or 2, characterized in that the output of the summing circuit (S1) via a contact (K) is connectable to the input of the delay chain (F1 - F8), and that a further delay chain (F21 - F35), a multiplicatlon unit (H2) ), a frequency analyzer (FA2) and a logic unit (L02) tlllsannans constitute a conversion device of basically the same type as the first-mentioned conversion device, the further delay chain (F21 - F35) comprising N + M - 1 delay element, where H is the number of excluded sample after a group of N samples and has its output connected to the input of the first-mentioned delay chain (F1 - F8), and wherein a switching circuit (0) in the further conversion device is arranged to switch the connections between the further delay chain ( F21 - F35) and the additional frequency analyzer (FA2) respectively. the further multiplication unit (H2) two steps (sample positions) towards the common connection point of the delay chains for each sample within a group of samples previously missing in the non-uniformly sampled signal, whereby the first-mentioned conversion device is responsible for generating a group of samples and the further the conversion device is responsible for generating an equal group of samples so that the originally non-uniformly sampled signal becomes uniformly sampled. Å. Plant acc. any of the preceding claims, characterized in that in a transmission line between a time-frequency converter (TFC2 in Fig. 6) and a frequency-time converter (FTC2 in Fig. 6) there is a switch (02) which is arranged to exclude in the transmitted signal of samples in the frequency domain as many samples as in the device according to the foregoing requirement is eliminated by a switch (01) present in these devices in the signal of the sample in the time domain, and the frequency-time converter (FTC2) is arranged in a manner known per se so that in a frequency-time conversion of a pattern of samples in the frequency domain transmitted through the transmission line, which is obtained from said time-frequency converter (TFC2) by time-frequency conversion in the latter of a first pattern of samples in the time domain brought to it to a pattern of samples in the frequency domain , and after exclusively by the switch (02) of some of the samples appearing in the latter pattern a pattern of samples in the time domain is obtained, which essentially corresponds to said, first pattern of samples.