RU168665U1 - DEVICE FOR GENERATING FREQUENCY-MANIPULATED RECTANGULAR PULSES - Google Patents

Abstract

The utility model relates to the field of radio engineering and can be used in radio transmitting devices, in measuring equipment as a source of rectangular pulses, frequency-manipulated. The device for generating frequency-manipulated rectangular pulses contains (Fig. 2) a logic element 2OR-NOT (1), MOS transistor (5) with an n-type channel, a manipulating (control) voltage generator (4), a U-shaped RC filter consisting of constant capacitors (6), (8) and a constant resistance resistor 7, a buffer log esky element composed of series-connected NAND gates (2) and (3) .Tehnicheskim result of the present utility model is to expand arsenal of technical means design generator FSK square pulses. The technical result is achieved due to the use of the 2 OR-NOT logic element (1) in the generator design, while the first input of the 2 OR-NOT logic element (1) is connected to the device’s common bus, as a result of which a sequence of rectangular frequency pulses manipulated by frequency is generated at the generator output.

Description

The utility model relates to the field of radio engineering and can be used in radio transmitting devices, in measuring equipment as a source of rectangular pulses, frequency-manipulated.

Achievable technical result - the expansion of the arsenal of technical means of design of a generator of frequency-manipulated rectangular pulses.

A known generator of frequency-manipulated rectangular pulses (Fig. 1), containing a logic element 2I-NOT (1), a MOS transistor (5) with an n-type channel, a generator (4) of a manipulating (control) voltage, a U-shaped RC- a filter consisting of constant capacitors (6) and (8) and a constant resistance resistor (7), a buffer logic element consisting of the first logical element NOT (2) and the second logical element NOT (3).

The purpose of the claimed technical solution is to expand the arsenal of technical means of the design of the generator of frequency-manipulated rectangular pulses by changing the design of the generator.

A functionally complete system of logical functions is a set of logical functions with which you can write any arbitrarily complex function. In this case, it is said that this set forms a basis. 3 bases are functionally complete: “AND-OR-NOT” (basis of conjunction, disjunction, inversion), “AND-NOT” (Schaeffer basis), “OR-NOT” (Pierce basis or Webb function) [2]. Therefore, in the future we will use the basis of the 2OR-NOT element (Pierce element) to generate frequency-modulated rectangular pulses.

The claimed device for generating frequency-modulated rectangular pulses (Fig. 2) contains a MOS transistor (5) with an n-type channel, a manipulating voltage generator (4), a U-shaped RC filter consisting of capacitors (6) and (8) and a resistor (7), a buffer element consisting of the first logical element NOT (2) and the second logical element NOT (3). The expansion of the arsenal of technical means for the construction of a generator of frequency-modulated rectangular pulses is achieved due to the fact that the logic element 2OR-NOT (1) is introduced into the circuit design.

The first output of the OR-NOT logic gate (2) is connected to the general output of the device power supply, the output of the OR-2 logic element (1) is connected to the input of the buffer logic element consisting of the first logical element NOT (2) and the second logical element NOT (3) ), while the output of the first logical element NOT (2) is connected to the input of the second logical element NOT (3), the output of the second logical element NOT (3) is the output of the device for generating frequency-manipulated rectangular pulses, the output of the logic element 2 OR NOT (1) is also connected to the source of the MOS transistor with an n-type channel (5), with the first output of the resistor (7) and the first output of the capacitor (8), the second input of the logic element 2 OR NOT (1) is connected to the drain of the MOS transistor with an n-type channel (5), with a second output of the resistor (7) and the first output of the capacitor (6), the first output of the 2-NOR gate (1), the MOS transistor substrate (5), and the second capacitor outputs (6 ) and (8) are connected to the common bus of the device’s power source, the potential output of the manipulating voltage generator (4) is connected to the MOS-gate transistor (5).

A device for generating frequency-manipulated rectangular pulses (Fig. 2) works as follows. The resistance R _{vT of a} MOS transistor with a channel, depending on the control voltage U _in, can take two values:

, если МОП-транзистор включен (находится в режиме насыщения),

if the MOSFET is on (in saturation mode),

, если МОП-транзистор выключен (заперт). Логический элемент 2ИЛИ-НЕ (1) устройства генерации частотно-манипулированных прямоугольных импульсов в цепи обратной связи содержит, в частности, сопротивление R_экв, образованное параллельно включенными выходом (исток-сток) МОП-транзистора с каналом n-типа (5) и резистором (7) постоянного сопротивления. В случае отсутствия управляющего напряжения на выходе генератора (4) манипулирующего напряжения, т.е. при напряжении, равном нулю, на затворе МОП-транзистора сопротивление R_экв=R_0экв представляет собой фиксированную величину, близкую к величине сопротивления резистора (7). Процесс генерации прямоугольных импульсов (фиг. 4) характеризуется постоянной частотойand

if the MOSFET is turned off (locked). The logical element 2OR-NOT (1) of the device for generating frequency-manipulated rectangular pulses in the feedback circuit contains, in particular, the resistance R _equiv formed by the parallel-connected output (source-drain) of the MOS transistor with an n-type channel (5) and a resistor (7) constant resistance. In the absence of control voltage at the output of the manipulating voltage generator (4), i.e. at a voltage of zero at the gate of the MOS transistor, the resistance R _equiv = R _0eq is a fixed value close to the value of the resistance of the resistor (7). The process of generating rectangular pulses (Fig. 4) is characterized by a constant frequency

) параллельно включенных выхода (исток-сток) МОП-транзистора (5) и резистора (7) постоянного сопротивления также существенно снижается, т.е.After the manipulating voltage generator (4) is turned on, a high-level voltage is supplied to the gate of the MOS transistor with an n-type channel, the MOS transistor goes into saturation mode, its resistance decreases sharply, the equivalent resistance (

) in parallel connected output (source-drain) of the MOS transistor (5) and the constant resistance resistor (7) also decreases significantly, i.e.

является величина сопротивления МОП-транзистора в режиме насыщения. В результате снижения величины эквивалентного сопротивления

время задержки сигнала с выхода логического элемента 2ИЛИ-НЕ (1) на его второй вход уменьшается, что приводит к росту частоты генерации прямоугольных импульсов (фиг. 4). При напряжении, равном напряжению логической единицы на затворе МОП-транзистора с каналом n-типа, генерация прямоугольных импульсов (фиг. 4) осуществляется с частотой следования импульсовEquivalent Resistance Reduction Limit

is the resistance value of the MOS transistor in saturation mode. As a result of reducing the equivalent resistance value

the delay time of the signal from the output of the logic element 2 OR NOT (1) to its second input decreases, which leads to an increase in the frequency of generation of rectangular pulses (Fig. 4). At a voltage equal to the voltage of a logical unit on the gate of a MOS transistor with an n-type channel, the generation of rectangular pulses (Fig. 4) is carried out with a pulse repetition rate

Where

Inequalities (4) are due to inequality (2). So, the pulse generation frequencies f ₁ and f ₀ are in the ratio

) начинается генерация прямоугольных импульсов с частотой следования f₁. Генерация будет продолжаться в течение времени, которое характеризуется высоким уровнем (уровнем логической единицы) управляющего сигнала на затворе МОП-транзистора с каналом n-типа. Переключение управляющего сигнала с высокого уровня (уровня логической единицы) на низкий уровень (уровень логического нуля) прекращает генерацию логическим элементом 2ИЛИ-НЕ прямоугольных импульсов с частотой следования f₁ (фиг. 4).At the moment of switching the manipulating signal from the state of logical zero to the state of the logical unit (voltage drop

) begins the generation of rectangular pulses with a repetition rate f ₁ . The generation will continue for a time that is characterized by a high level (logical unit level) of the control signal at the gate of the MOS transistor with an n-type channel. Switching the control signal from a high level (logical unit level) to a low level (logical zero level) stops the generation of 2 or NOT rectangular pulses by a logic element with a repetition rate f ₁ (Fig. 4).

The buffer is turned on after the logic element 2 OR NOT (1), it is the output component of the device for generating frequency-manipulated rectangular pulses. The use of inverters as a logical buffer output device provides improved shape of the generated pulses by increasing the steepness of their fronts.

на затворе МОП-транзистора с каналом n-типа сопротивление канала МОП-транзистора (5) изменяется скачком, оно возрастет, сопротивление

также увеличится и станет равным величине сопротивления R_0экв, так как пределом увеличения эквивалентного сопротивления

является величина сопротивления резистора (7). Таким образом,With voltage drop

on the gate of a MOS transistor with an n-type channel, the resistance of the channel of the MOS transistor (5) changes abruptly, it increases, the resistance

also increases and becomes equal to the value of resistance R _0eq , since the limit of increase in equivalent resistance

is the resistance value of the resistor (7). In this way,

время задержки сигнала с выхода логического элемента на его второй вход увеличивается, что приводит к снижению частоты генерации прямоугольных импульсов (фиг. 2). При напряжении, равном напряжению логического нуля на затворе МОП-транзистора, генерация прямоугольных импульсов (фиг. 4) снова осуществляется с частотой следования импульсов f₀. Итак, частота генерации прямоугольных импульсовAs a result of an increase in equivalent resistance

the delay time of the signal from the output of the logic element to its second input increases, which leads to a decrease in the frequency of generation of rectangular pulses (Fig. 2). At a voltage equal to the logic zero voltage at the gate of the MOS transistor, the generation of rectangular pulses (Fig. 4) is again carried out with a pulse repetition rate f ₀ . So, the frequency of generation of rectangular pulses

The generation of rectangular pulses with a frequency f ₂ will continue for a period of time characterized by a low level (logical zero level) of the control signal at the gate of the MOS transistor. Switching the control signal from a low level (logical zero level) to a high level (logical unit level) stops the generation of 2 or NOT pulses with a repetition rate f ₂ .

The result is a frequency-manipulated sequence of rectangular pulses. The transition from the generation frequency f _{1 of the} generation of rectangular pulses to the generation frequency f ₂ (as the transition from the generation frequency f ₂ to the generation frequency f ₁ ) occurs without breaking the signal phase of the generated rectangular pulse sequence.

на затворе МОП-транзистора сопровождается генерацией прямоугольных импульсов на частоте f₁ (5), а перепад напряжения

на затворе МОП-транзистора сопровождается генерацией прямоугольных импульсов на частоте f₂ (9). Частоты генерации f₂, f₁ прямоугольных импульсов согласуются с неравенством f₂<f₁.A simulation of a device for generating frequency-manipulated rectangular pulses on a logical element 2OR-NOT (1) (Fig. 3). The following were used: 2OR-NOT chip type 74F02D, in a U-shaped RC filter R (7) = 10 kOhm, C (6) = 1 pF, C (8) = 1 pF. Transistor channel parameters: l = 0.35 μm, w = 0.7 μm. For clarity of the simulation results, the frequency of the control (manipulating) signal is assumed to be 500 kHz. A time diagram of the output signal of the simulated pulse-generating device is obtained (Fig. 4), which illustrates the process of generating a frequency-manipulated sequence of rectangular pulses by the generating device using a 2 OR-NOT logic element (1) and a MOS transistor with an n-type channel (5). In this case, the voltage drop

at the gate of the MOS transistor is accompanied by the generation of rectangular pulses at a frequency f ₁ (5), and the voltage drop

at the gate of the MOS transistor is accompanied by the generation of rectangular pulses at a frequency f ₂ (9). The generation frequencies f ₂ , f _{1 of} rectangular pulses are consistent with the inequality f ₂ <f ₁ .

The simulation results are given in table. one.

Thus, the claimed utility model provides an expansion of the arsenal of technical means for the construction of a generator of frequency-manipulated rectangular pulses due to the use of a 2 OR-NOT logical element in the design of a generator (1).

Literature

1. Patent RU 160958 U1 "Generator of frequency-manipulated rectangular pulses." Mushta A.I., Shekhovtsov D.V. Published 04/10/2016.

2. Electronic resource: http://life-prog.ru/view_programmer.php?id=60&page=6

Claims (1)

A device for generating frequency-manipulated rectangular pulses containing a MOS transistor with an n-type channel, a manipulating voltage generator, a U-shaped RC filter consisting of capacitors and a resistor, a buffer logic element consisting of the first logical element NOT and the second logical element NOT , characterized in that the logical element 2 OR is NOT added, expanding the arsenal of technical means of the device design, the first output of the logic element 2 is NOT connected to a common power bus of the device, output l of the logical element 2 is NOT connected to the input of the buffer logic element consisting of the first and second logical elements NOT connected in series, while the output of the first logical element is NOT connected to the input of the second logical elements NOT, the output of the second logical element is NOT the output of the frequency-manipulated generator rectangular pulses, the use of inverters as a buffer output device provides improved shape - the steepness of the fronts generated by the frequency-manip of rectangular pulses, the output of the OR gate is NOT connected also to the source of the MOS transistor with an n-type channel, to the first output of the resistor and the first terminal of one capacitor, the second input of the logic gate 2 OR is NOT connected to the drain of the MOS transistor, with the second terminal the resistor and the first terminal of another capacitor, the substrate of the MOS transistor, as well as the second terminals of the capacitors are connected to a common power bus of the device, the potential output of the manipulating voltage generator is connected to the gate of the MOS transistor torus, when hopping - differentials 0 → 1 and 1 → 0 control voltage - the signal is generated without phase discontinuity sequence FSK square pulses with frequencies f_one and f₂ respectively, with f_one> f₂, generation of rectangular pulses with frequencies f_one and f₂ due to sharp changes in the resistance of the channel of the MOS transistor, leading to a significant change in the resistance of the feedback circuit of the logic element 2 OR NOT, and therefore the transit time of the signal from the output of the logic element 2 OR NOT to its second input upon receipt of each of the differences 0 → 1 and 1 → 0, respectively, the voltage of the control generator to the gate of the MOS transistor.

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