SU999152A1 - Pulse-time code decoder - Google Patents

Description

(54) PULSE-TIME CODES DEFAULT

The invention relates to a pulse technique and can be used in multipulse receivers.

Pulse-time code decoders are known that contain a delay line and code group selectors whose inputs are connected to the corresponding taps of the delay line, and the selector outputs are device outputs. The selectors are made either in the form of AND elements registering the coincidence of all code-group pulses, or in the form of logical threshold elements with a digital threshold r, registering a coincidence r of n code group pulses}.

In modern pulse-time code decoders, a shift register is usually used as a delay line, since electromagnetic delay lines have a low parameter stability when operating conditions change, especially ambient temperature and its amplitude and pulse width at the gate.

The known decoder pulse-time codes, made with primeneni4 "| the shift register, the contents of the shift register, whose information input is the input of the decoder, and the code selectors. groups, the first inputs of which are connected to the information input of the register, and the second and subsequent inputs are connected to the outputs of the corresponding register cells, and the output

The 10 selectors are the outputs of the decoder, as well as the generator of shift pulses, the output of which is connected to the shift input of register C2.

15

The disadvantage of such a decoder is the dependence of the resolution on the discretization ratio of the shift register // "T / T ,,, where T is the period of the shift pulses,

20 arriving at the register, and T is the pulse duration of the code groups to be decoded. The larger the /, the worse the resolution of the discrete decoder. Therefore, to increase the resolution of the decoder, it is necessary to reduce the period of shear pulses, T, which, for a fixed duration of code groups, entails an increase in

The 30th number of register cells, i.e. significant increase in hardware costs,

The purpose of the invention is to increase the resolution of the decoder without increasing the number of shift register cells.

This goal is achieved by the fact that in a pulse-time code decoder containing a shift register, the information input of which is connected to the device input, code group selectors, the first inputs of which are connected to the information input of the shift register, and the second and subsequent selector inputs are connected to the outputs of the corresponding cells register shift, the outputs of the selectors are connected to the outputs of the decoder, the generator of shift pulses, the output of which is connected to the shift input of the register, introduced k-input elements And about the number of code group selectors, the OR element and the frontalization block, the installation. input of the shear pulse generator is connected to the output of the OR element, whose inputs are connected to the outputs of the AND elements, the first inputs of which are connected to the information input of the register, and the second and the subsequent inputs of the And elements are connected to the outputs of the corresponding cells of the shear.register.

The essence of the invention is that, using the elements of AND, select the first k pulses of the code group to be decoded and c. the moment the pulse is released, the coincidences are made asynchronization of the shear pulses. Due to this, the subsequent pulses of the code group arrive in the register synchronously with the shear pulses, which is equivalent to reducing the shift period and gives a corresponding increase in the decoder capacity. .

FIG. 1 shows a structural diagram of a decoder; FIG. 2 diagrams explaining the invention,.

The decoder contains a shift register 1, selectors of 2 code groups, a generator of 3 shift pulses, made in the form of serially connected reference generator 4 and counter 5, a front selection block, an OR element 7 and AND 8 elements. The input of the device is the information input of the register, and device outputs - selector outputs. The number of selectors m is the number of interpretable pulse-time codes, the number of elements And is equal to the number of selectors.

The device works as follows.

The information input of register 1 receives the signals of decrypted code groups, which are recorded in register cells as symbols 1 and advanced through the register with the help of shift pulses coming from reference generator 4 via counter 5,

5 The pauses between pulses are written to the register with O. symbols. The inputs of the selectors of 2 code groups are connected to the corresponding register cells. At the point in time when the g inputs

1st selector simultaneously present pulses of the code group, i.e. at the outputs of the corresponding register cells the symbols 1, at the output of the selector a signal appears, of fixings

5 reception of the corresponding t-th code group.

In the process of decoding the i- and code group, subsynchronization of the shear comb, pulses, is performed.

0 For this, using the element AND 8, the instant of arrival of the first k pulses of the i-th code group is singled out. The impulse of coincidence through the element OR 7 goes to the block 6

5 edge, where the leading edge of the coincidence pulse is highlighted. Then, using this pulse, the instantaneous setting of the counter 5 in a certain state is performed, which ensures the highest resolution of the decoder for the remaining n-k pulses of the given code group.

The resolution of the decoder, i.e., its ability to distinguish pulse-time codes by the length of the code interval between pulses, is determined by those maximum deviation values from the nominal value of the code interval between two pulses, for which

0 a coincidence pulse is generated. If the arrival times of the code group pulses are random and are distributed evenly on the period T of the shear pulses (Fig. 2a, b), then the decisive power of the decoder dV is determined by the diagram shown in Fig. 2g. At the same time resolution, t, e. minimum value of CODE interval, reliably

0 distinguishable by this decoder

6 2 (Ti + T).

The best resolution occurs with such a sub-synchronization of the shear comb, when the front of the code group pulse falls exactly in the middle of the interval between two adjacent shear points (Fig. 2c). In this case, the largest deviations of the code interval value for reliable distinction cannot exceed ± 0.5 T, and the resolution of the decoder / is ((Fig. 2d). .

SNF-,), 2 (m + 0.5T) sG & -,

those. higher than in the absence of subsynchronization and equivalent to the well-known decoder with a shift period of T 0.5T, for the implementation of which it is necessary to double the number of register cells.5

Example. Let TCs be 0.5 μs and the duration of the code groups Skg 32 ISS, i.e. the volume (number of cells) of the register Ir С | Цг / Т 64. in the known decoder the breaking capacity pt 2 ISS, and in the proposed 1.5 ISS. In order to obtain the same resolution in a known decoder, it is necessary to take a shift period of 0.25 microseconds, and in connection with 15, the register volume rises to pr 2pr 128 cells.

For ensuring the highest resolution of your ability, i.e. in order for the leading edge of the pulse of the code group M to be placed exactly in the middle of the period of the shift pulses, the counter 5 must be set to the subsynchronization pulse coming from the extracting unit 6 to the 25 state 0.5 S, where S is the division factor provided by the counter - com 5.. .

For single-noise interference, the number k of input elements And 8 must be at least two. On the other hand, the number of inputs of these elements must be less than the threshold of the selector of the code group g. From these considerations, we obtain a ratio for the definition of 35 or K: 2i .

Since the increased resolution begins to act from the reception of the (K + 1) th pulse of the code group, the efficiency of the predicted decoder is the smaller the K.

Thus, the proposed decoder has the same resolution, which would have known decoder with twice the number of register cells. Therefore, the use of the proposed decoder avoids an increase in the apparatus. required to ensure the required resolution. 50

Particularly effective is the proposed dayfrator in receivers of VIM-IVK-AM. In this embodiment, as the AND element, a start code group selector is used, upon reception of which a shift comb is synchronized to receive information code groups with maximum resolution.

Claims (2)

1.Tipugin V.N. Weizel V.A. Radio control. M., Soviet Radio 1962, p. 452-454, fig. 7-24. 2.Tipugin V.I., Weizel V.A. Radio control. M., Soviet, 1962, p. 75, fig. 15 (prototype). ABOUT Gi (Zn.-tT) Jlt tM Sf ffa + o, $ t} Rdeck f.O  Lg