SU802987A1 - Radio signal simulator - Google Patents

Description

(54) RADIO SIMULATOR

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This invention relates to radio signal simulators and may be used for the training of radio operators.

A radosignup simulator is known, comprising a master oscillator coupled through a pulse waveform transducer node With a radio frequency signal transducer node l J

The disadvantage of the known simulator is the low efficiency of signal simulation.

The purpose of the invention is to increase the efficiency of signal imitation.

The goal is achieved by the fact that the simulator has a clock shaping node, one of the inputs of which is connected to the output of the master oscillator, and its other inputs are connected to one of the outputs of the f-conversion node (pulse signals, and the outputs of the clock shaping node are associated with one of the inputs of the pulse waveform transducer node, with the input of the transducer node into the radio frequency signal with the master oscillator, and the output with the pulse signal transducer node. clock pulse generator is connected vstrechnoparallelno clock pulses and lane sgoochatel.

FIG. 1 shows the simulator structural diagram in FIG. 2 and 3 are graphs of the change in the shape of the simulated signal with a change in the frequency of the clock pulses and the immeasurable structure of the formation device; in fig. 4 - clock pulse shaper and switch; Wah FIG. 5 is the same as the embodiment.

Claims (2)

Simulator master oscillator 1, driver of 2 timing diagrams, converter of 3 pulse signals, node 4 of formation of clock pulses, driver of 5 clock, switch 6, generator 7 of frequency disconnection, radio frequency filter 8, output block 9, trigger 1O, fan (logic circuit ) 11, the logic circuit OR 12 and the shaping of 13 pulses. The nodal transformation of the shape of the impulse signals contains the shaper of 2 time diagrams and the transducer 3 of the shape of the pulse signals. The RF signal conversion unit has a carrier frequency generator 7, a radio frequency filter 8 and an output unit 9. The simulator operates as follows. The signal from the generator 1 is fed to the driver 2, in which a sequence of pulses is formed, corresponding to the timing diagram of the generated signals, the next pulse from the generator 3 is fed to the converter 3, in which its shape is changed using a digital analog converter, and the form of the simulated pulse is set. signal, then it arrives at the output unit 9 through the radio-frequency filter 8. The carrier frequency and signal being generated is given by the signal of the carrier frequency generator 7, also on the converter 3. Setting the pulse form in the digital converter, the coa analogue requires a significant number of elements defining the form (logic circuits, keys, resistors). The simulator provides the formation of various forms of simulated signals with the same elements of the converter 3. This is ensured by the fact that the converter 3 is connected to the master oscillator 1 through the node 4 forming the clock pulses. In the process of forming the fronts of the pulse signals by the transducer 3, control signals are sent from node 4 to node 4; when they arrive, the parameters that characterize the operation of the simulator, for example, the frequency of clock pulses from node 4 to converter 3, or they are fed to other inputs of converter 3, result in changing the shape of the simulated signal (see Fig. 2 and 3) . FIG. 2 impulse corresponds to the formation of a signal at a constant frequency of clock pulses, impulse Obb halves the frequency of such impulses from the moment corresponding to the top of the signal. In this case, the pulse duration and its shape vary. By varying one or another law to the clock frequency of pulses in node 4, it is possible to change the initial pulse shape within wide limits without changing the elements of the converter 3 and its structure. This is evident from the graphs shown in FIG. 3. Let converter 3 with a constant clock pulse frequency ensure the formation of a linearly increasing signal front (Fig. 3a), then when the frequency in node 4 changes according to less-less-less, the linear rise-in time of the front will be converted to FIG. 3.6. Thus, using an arresting pulse shape converter 3, which provides a linear formation law, one can obtain a non-linear law of the rise of the pulse front. The control signals from block 3 are fed to node 4, in the result of this, the frequency of the clock pulses fed to block 3 is changed, and the shape of the simulated signal is changed. Node 4 includes a clock pulse shaper 5 and switch 6. The shaper 5 can be designed as a frequency divider, the frequency of the output pulses can be changed by controlling the divider division factor, which uses a counter (divider) with a variable controlled conversion factor; change the frequency of the output pulses. It can also be done by connecting the output circuit to one or another bit of the splitter counter with a switch, which can be used as a switch 6 (see Fig. 4). The shaper of 5 clock pulses is made in the form of a splitter of the counter on the Y triggers. The output of the bit of the splitter is connected to the inputs of switch 6, performed on AND 11 and OR 12 logic circuits. Control of switch 6 is performed by signals of And 3 logic circuits When one or another control signal is received, one or another bit of the divider of the counter 5 is connected to the output, which ensures the change in the frequency of the clock pulses fed to the block 3. In FIG. 5 shows another example of the implementation of blocks 5, 6 of node 4.. Here, the control signals from block 3 are sent to the triggers 1O of the splitter counter of block 5 through logic circuits 11 of switch 6 at the time determined by the formation time of the output pulse by circuit 11 of block 5, which is supplied both to block 3 and through the shaper 13 pulses to the second inputs of logic circuits AND 11. Claim 1. Radio signal simulator / juv containing a master oscillator connected through a pulse waveform transducer to the node is converted a radio frequency signal, characterized in that, in order to increase the effectiveness of simulation signals, it has a clock signal generating unit, one of whose inputs is connected to the oscillator output, and its other input coupled to one of the output node Figure 2 transforms the waveform of the signals, the outputs of the clock shaping node are connected to one of the inputs of the pulse waveform node, the input of the radio frequency signal converting node is connected to the master oscillator, and NUXOO is connected to the pulse waveform converting node. 2. The simulator according to claim 1, about a hp and with the fact that the fs clock clock pulse node has the fs globator of clock pulses and a switch connected in counter-parallel way. Sources H1 “of the law that were taken into account during the examination. 1. USSR author's certificate in application N 2359679 / 18-12 ,, cl. G O9 B 9 / OO, 1976 (prototype). Have one .