RU2445690C2 - Correlated metre of time shifts - Google Patents

Abstract

FIELD: information technologies.

SUBSTANCE: invention may be used to build systems of extraction of coordinate and time information, the principle of operation of which is based on detection of a time shift between the received signals. The metre realises the method to detect a correlated function with paired non-correlated samples and comprises an input analog multiplexer, an analog-to-digital converter, a register, a decoder, a multiplier, a group of accumulating summators, a unit of extremum finding and a control unit.

EFFECT: hardware simplification in a correlated metre.

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Description

The invention relates to specialized signal processing tools and can be used in the construction of coordinate-time information extraction systems, the principle of which is based on determining the temporal shift between received signals.

A known correlation meter of time shifts, containing two correlators, a subtraction unit, an adjustable delay unit, a constant delay unit, an amplifier and two controlled filters, the outputs of the first and second correlators are connected to the corresponding inputs of the subtraction unit, the output of which is connected through an amplifier to the control input of the adjustable unit delay, the output of which is directly and through the constant delay unit respectively connected to the first inputs of the first and second correlators, the second inputs of which connected to the output of the first controlled filter, the output of the second controlled filter is connected to the information input of the adjustable delay unit, the information inputs of the first and second controlled filters are the first and second inputs of the device, the control inputs of the first and second controlled filters are combined and connected to the output of the amplifier [ed. St. USSR No. 1101837. Publ. in BI No. 25, 1984].

The disadvantage of a correlation meter is the large hardware volume.

The closest in technical essence to the proposed correlation meter is a correlation meter of time shifts, containing an analog-to-digital converter, a register, a multiplier, a group k of accumulating adders, a multiplexer, two demultiplexers, an extremum search unit and a control unit, the multiplexer output is connected to the analogue information input a digital converter, the output of which is connected to the information input of the first demultiplexer, the first output of which is connected to the information the input of the register, the output of which is connected to the first input of the multiplier, the second input of the multiplier is connected to the second output of the first demultiplexer, the output of the multiplier is connected to the information input of the second demultiplexer, the k outputs of which are connected to the information inputs of the corresponding k accumulating adders, the outputs of which are connected to the corresponding k information inputs an extremum search unit, the output of which is the output of the meter, the information inputs of the meter are respectively the first and the second information inputs of the multiplexer, the address input of which is combined with the address input of the first demultiplexer and connected to the first address output of the control unit, the second address output of which is connected to the address input of the second demultiplexer, the first, second and third clock outputs of the control unit are connected to the clock inputs of analog-digital converter, register and accumulating adders, respectively, the zeroing inputs of accumulating adders are combined with the zeroing input of the extremum search block and connected to the zeroing output of the control unit, the control output of which is connected to the triggering input of the extremum search block, the inputs of the start and zeroing of the correlation meter are the corresponding inputs of the control unit, the register output is connected to the first input of the multiplier [RF patent No. 2229157. Publ. in BI No. 14, 2004].

The disadvantage of the prototype is the complexity of its implementation, which is especially evident when working with multi-bit operands, for sending which the prototype uses multi-channel multi-bit demultiplexers.

The technical result achieved by using the present invention is to simplify the correlation meter by eliminating demultiplexers from its composition.

The technical result is achieved by the fact that in a known correlation meter of time shifts, containing a multiplexer, analog-to-digital converter, register, multiplier, group k of accumulating adders, an extremum search unit and a control unit, the multiplexer output is connected to the information input of an analog-to-digital converter, register output connected to the first input of the multiplier, the outputs of k accumulating adders are connected to the corresponding k information inputs of the extremum search block, the output of which I is the output of the meter, the information inputs of the meter are respectively the first and second information inputs of the multiplexer, the address input of which is connected to the first address output of the control unit, the first, second and third clock outputs of the control unit are connected to the clock inputs of the analog-to-digital converter, register and accumulating adders, respectively , the zeroing inputs of the accumulating adders are combined with the zeroing input of the extremum search block and are connected to the zeroing output of the control unit The control output of which is connected to the triggering input of the extremum search unit, the inputs of the start and zeroing of the correlation meter are the corresponding inputs of the control unit, according to the invention, a decoder is introduced, the information input of which is connected to the second address output of the control unit, the output of the analog-to-digital converter is connected to the information input register, the second input of the multiplier is combined with the information input of the register, the output of the multiplier is connected with the combined information input mi k accumulating adders whose permissible inputs are connected to the corresponding k outputs of the decoder.

The invention is illustrated graphic material.

Figure 1 shows a functional diagram of a correlation meter of time shifts; figure 2 is a timing diagram illustrating the operation of block 8 of the control.

Functional diagram of the correlation meter (Fig. 1) contains an input analog multiplexer 1, analog-to-digital converter (ADC) 2, register 3, multiplier 4, decoder 5, group 6 k of accumulative adders, extremum search unit 7, and control unit 8. The output of the multiplexer 1 is connected to the information input of the ADC 2, the output of which is connected to the information input of the register 3, the output of which is connected to the first input of the multiplier 4, the second input of which is combined with the information input of the register 3, the output of the multiplier 4 is connected to the combined information inputs of k accumulating adders 6 , k outputs of the decoder 5 are connected to the enabling inputs of the corresponding accumulating adders of group 6, the outputs of which are connected to the corresponding information inputs of the search unit 7 three, the output of which is the output of the meter, the inputs X and Y of the meter are respectively the first and second information inputs of multiplexer 1, the address input of which is connected to the address output A1 of the control unit 8, the address output A2 of which is connected to the information input of the decoder 5, clock inputs CLK1, CLK2 and CLK3 of control unit 8 are connected to the clock inputs of the ADC 2, register 3, and accumulating adders 6, respectively, the zeroing inputs of the adders of group 6 are combined with the zeroing input of block 7 and are connected to the output RST1 of the control unit 8, the control output of which is connected to the trigger input of the extremum search unit 7, the inputs of the CO control and zeroing of the RST of the correlation meter are the corresponding inputs of the control unit 8.

The timing diagrams of FIG. 2 relate to the particular case of k = 3 and contain address pulses A1 (FIG. 2a) at the first address output of block 8; clock pulses CLK1 (figb) at the first clock output of block 8; clock pulses CLK2 (pigv) on the second clock output of block 8; clock pulses CLK3 (Fig.2d) at the third clock output of block 8; the current address code A2 (fig.2d) at the second address output of block 8.

The correlation meter works as follows.

Before starting the start, the control unit 8 (Fig. 1) is zeroed by applying a pulse to the RST input, thus putting the unit into standby mode of the starting pulse. The correlation meter is started by supplying a triggering pulse to the input CO, after which the control unit 8 starts supplying clock pulses CLK1, CLK2 and CLK3 (fig.2b, c, d) to the clock inputs of the ADC 2, buffer register 3 and accumulating adders 6, respectively. At the initial moment of time t _i, for example, at time t ₀ , the signal x (t), that is, x (t ₀ ), enters the input of register 3. This is set by applying a logical unit to the address input of multiplexer 1 (Fig. 2a), which switches the signal x (t) to the ADC input 2. To write the specified count into the register, the clock pulse of the CLK2 sequence is used, after which the count x (t ₀ ) appears at the inputs of the multiplier 4, as a result of which, temporarily, during one clock interval, at the output of the multiplier 4 we have a square of the indicated value - x ² (t ₀ ). However, the obtained value is not involved in the calculations. Next, a command (low logic level) is sent to the address input of multiplexer 1 from the control unit 8, which switches multiplexer 1 to another switching mode, namely, the signal y (t) is switched to the input of ADC 2, and from the output of ADC 2 the signal is sent to the second input multiplier 4, at the first input of which there is already a sample x (t ₀ ) stored in register 3. At the same time, writing a new value to register 3 does not occur, since the writing process is possible only if there is a clock pulse CLK2, which in turn is generated only at comm uu reference signal x (t). Considering that the clocking of ADC 2 occurs with an interval At, we have a sample y (t ₀ + Δt) at the output of ADC 2. Thus, the time t ₀ + Δt corresponds to the appearance at the output of the multiplier 4 of the product x (t ₀ ) y (t ₀ + Δt), which is sent to the information input of the accumulating adder 6-1. ADC 2 digitizes the values of the signal y (t) during the cycle. K times and, therefore, at the output of the multiplier 4 during the cycle K products of the form

x (t ₀ ) y (t ₀ + kΔt), k = 1, 2, ... K.

Each of these works is sent to the corresponding channel accumulating adder from group 6 according to the rule: ke is the product in the kth adder. For switching the results of multiplication of samples, a decoder 6 is used, controlled by the address code (Fig.2d), coming from the output A2 of the control unit 8. The decoder supplies the enabling pulses to the corresponding adders of group 6 in such a way that, in the presence of the kth product, the operation of the kth adder is allowed. At the end of the cycle, after the last (k + 1) th clock pulse of the cycle, the logic unit level is again set at the address input of multiplexer 1, as a result of which the signal x (t) is fed to the input of the ADC 2, and the next sample x is output from the ADC 2 (t _{i + 1} ), in our example x (t ₁ ), to the input of buffer register 3, where it is stored during the entire cycle of calculations. Also, as in the previous cycle, in this cycle, the formation of samples y (t ₁ + kΔt) occurs, in our example y (t _i + kΔt), which, after multiplying by x (t ₁ ), are distributed over the adders of group 6, in each of which summation occurs with the previously obtained result.

The extremum search unit 7 searches for the largest amount by which a decision is made on the position of the ordinate of the cross-correlation function R (τ) with the largest value, that is, determining the position of the peak of the function R (τ). The final result, the desired delay time, the estimate of τ * is calculated with a discrete Δt by the formula:

τ * (k, Δt) = kΔt,

where k is the sequence number of the channel adder of group 6, in which the largest amount is fixed.

The signal connections shown in the diagram (Fig. 1) in the ADC circuit 2 - register 3 - multiplier 4 - group of adders 6 - block 7 should be implemented in the form of multi-bit buses (in the diagram of Fig. 1, the links are conventionally shown as single-line circuits without indicating bit depth).

The extremum search unit 7 and the control unit 8 are identical to those used in the prototype [RF patent No. 2229157. Publ. in BI No. 14, 2004]. We emphasize that the correct control of the meter involves zeroing before starting the measurements of the accumulating adders 6 and block 7. The zeroing signal is received from the output RST1 of the control unit 8 simultaneously with an external reset pulse to the input of the RST unit 8. In the simplest case, this is ensured by the direct connection of the output RST1 of block 8 with its input RST.

Regarding the connection of the outputs of the decoder 5, we note the following. In connection with the features of the formation of the address code (Fig.2d) when using a decoder with traditional sequential addressing, it is necessary to connect the decoder output, activated at the address corresponding to the binary code of the number “2”, to the second channel (adder) to the first channel (adder 6-1) 6-2) - the output corresponding to the binary code of the number "3", etc. in ascending order, and the last channel, in our case the third, should correspond to the address code of zero. As a result, enumeration of channels with useful information in the decoder itself will start from the second, and end with zero. The address at which the first output channel of the decoder is called is not used, because according to the sequence of operations of multiplying samples in cycles into this clock interval (zero clock interval), only the multiplier is prepared for calculations during the cycle.

The accumulating adders of group 6 are implemented according to the well-known scheme containing the adder and the register covered by feedback, see, for example, [Novikov Yu.V. Basics of digital circuitry. Basic elements and schemes. Design Methods. - M .: Mir, 2001, p. 150, Fig. 4.24]. The permissive input in the adder can be arranged using an additional element 2I, the output of which is connected to the clock input of the accumulating adder register, while the first input of element 2I will act as the clock input of the accumulating adder, and the second input will function as the enable input.

In the claimed meter, unlike the prototype, there are no multi-channel demultiplexers designed for switching multi-bit digital data. In this case, the multi-digit digital code is sent from the output of the multiplier 4 to the information inputs of the accumulating adders 6 via one information bus (Fig. 1), to which all the adders are connected (in fact, the switching process has been replaced by the process of issuing signals allowing the reception of the results of multiplication). As for the presence in the circuit of the decoder 5, which is not in the prototype, it as a digital device is much simpler than a multi-bit demultiplexer, does not contain multi-bit outputs and is intended only for generating control signals at k single-bit outputs of the decoder.

Claims (1)

A time shift correlation meter containing a multiplexer, an analog-to-digital converter, a register, a multiplier, a group of k accumulative adders, an extremum search unit and a control unit, the multiplexer output is connected to the information input of an analog-to-digital converter, the register output is connected to the first input of the multiplier, outputs k accumulating adders are connected to the corresponding k information inputs of the extremum search block, the output of which is the output of the meter, information inputs from The first and second information inputs of the multiplexer are, respectively, the address input of which is connected to the first address output of the control unit, the first, second and third clock outputs of the control unit are connected to the clock inputs of the analog-to-digital converter, register and accumulating adders, respectively, the zeroing inputs of the accumulating adders are combined with the zeroing input of the extremum search block and connected to the zeroing output of the control unit, the control output of which is connected to the triggering the input of the extremum search block, the start and zero inputs of the correlation meter are the corresponding inputs of the control unit, characterized in that a decoder is inserted into it, the information input of which is connected to the second address output of the control unit, the output of the analog-to-digital converter is connected to the information input of the register, the second input the multiplier is combined with the information input of the register, the output of the multiplier is connected with the combined information inputs of k accumulating adders, allowing inputs, which are connected to the corresponding k outputs of the decoder.

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