RU121116U1 - ACOUSTIC CONTROL UNIT - Google Patents

Abstract

1. The control unit is acoustic, containing a microphone unit with a microphone, a delay unit, a hysteresis unit containing a reference voltage source, while the signal output of the delay unit is connected to the signal input of the hysteresis unit, characterized in that the microphone unit contains a series circuit of power supply and microphone resistance, the connection point of which is connected through a capacitance to the first input of the first comparator, while the first input of the first comparator is connected through a divider filter to the second input of the first comparator, and through the first feedback is connected to the output of the first comparator, while the output of the first comparator is also connected to the signal input delay unit, while the hysteresis unit contains a second comparator, the first input of which is a signal input of the hysteresis unit, and the second input of which is connected to the reference voltage source and through the second feedback is connected to the output of the second comparator. ! 2. The control unit according to claim 1, characterized in that the output stage of the first comparator is made with an open collector, the first input of the first comparator is positive, and the second input is negative, while the first feedback is capacitive positive feedback, and the divider filter made in the form of a voltage divider built on the first and second resistances, parallel to the second resistance, the filter capacitance is connected. ! 3. The control unit according to claim 1, characterized in that the delay unit is made in the form of a series circuit of delay resistance and delay capacitance, the connection point of which is both signal input and output

Description

The field of technology.

The inventive utility model relates to control circuits of electrical circuits, and is mainly intended for use in electrical light sources, in particular, in LED lamps.

The prior art.

Known LED lamp containing a control unit with an acoustic sensor and an LED unit containing light emitting diodes (LEDs). Moreover, the control unit contains means for turning on / off the LEDs depending on the signal of the acoustic sensor, moreover, said means is made to ensure the value of the acoustic threshold for turning off the LEDs is less than the value of the acoustic threshold for turning them on. This tool contains:

- shaper of the acoustic sensor signal, to the input of which an acoustic sensor is connected;

- block off delay, the input of which is connected to the output of the shaper of the acoustic sensor signal;

- an executive unit, to the control input of which the output of the turn-off delay unit is connected, to the first information input of which the output of the turn-on threshold driver is connected, and the output of the turn-off threshold former is connected to the second information input.

In this case, the power input and output of the executive unit are connected in series to the LED unit. (RF patent for utility model No. 99901, IPC H01L 33/00, 2010 [1]).

The disadvantage of this device is the low accuracy of controlling the level of response of the control eye, as well as the difficulty of implementing large delays in the active level of the control signal.

Another disadvantage of this device is the presence of two formers thresholds on and off, which increases the material consumption of the device.

Disclosure of a utility model.

The technical result provided by the claimed utility model is to increase the accuracy of setting the response level of the acoustic control unit, reducing its material consumption.

contains a microphone unit with a microphone, a delay unit, a hysteresis unit with a reference voltage source. In this case, the signal output of the delay unit is connected to the signal input of the hysteresis unit. In this case, the microphone unit contains a serial circuit of the power and microphone impedances, the connection point of which through the capacitance is connected to the first input of the first comparator. In this case, the first input of the first comparator is connected through a filter divider to the second input of the first comparator, and through the first feedback is connected to the output of the first comparator. The output of the first comparator is also connected to the signal input of the delay unit. In this case, the hysteresis unit contains a second comparator, the first input of which is the signal input of the hysteresis unit, and the second input of which is connected to the reference voltage source and connected to the output of the second comparator through the second feedback.

According to a preferred embodiment, the output stage of the first comparator is made with an open collector, the first input of the first comparator is positive, and the second input is negative. In this case, the first feedback is capacitive positive feedback. In this case, the filter divider is made in the form of a voltage divider built on the first and second resistances, and a filter capacitance is connected in parallel with the second resistance.

The delay unit can be performed in the form of a series circuit of delay resistance and delay capacitance, the connection point of which is simultaneously the signal input and output of the delay unit.

In a preferred embodiment, the first input of the second comparator is positive and the second input is negative. In this case, the second feedback is active negative feedback. In this case, the voltage reference is made in the form of a voltage divider.

The control unit can be equipped with a power source, the output of which is connected to the power resistance, as well as to the power inputs of the delay unit and the hysteresis unit.

The control unit may be carried out containing a power switch, the control input of which is connected to the output of the second comparator.

A brief description of the drawings.

Figure 1 shows a diagram of an acoustic control unit, figure 2 shows a preferred circuit of a comparator unit, figure 3 shows a preferred circuit of a delay unit, figure 4 shows a preferred circuit of a hysteresis block, and figure 5 shows a diagram of a control unit with a power source and power key, Fig.6 is a diagram of an example of a power supply, Fig.7 is a diagram of the use of an acoustic control unit.

Options for implementing a utility model.

The acoustic control unit 1 contains (figure 1):

- microphone unit 2;

- comparator unit 3;

- delay unit 4;

- hysteresis block 5.

The acoustic control unit 1 is provided with an input 30 and an output 31 of power, as well as an output of control 32.

The microphone unit 2 is designed to convert acoustic vibrations of the environment into an electrical signal and its preliminary preparation for supply to the comparator unit 3. Between the input and output power of the microphone unit 2, a power resistance 6 and a microphone 7 are connected in series, the connection point of which is connected through the capacitance 8 to the signal output 33 of the microphone unit 2.

The comparator unit 3 is designed to generate a primary digital pulse control signal. The comparator unit 3 is provided with a power input and output, as well as a signal input 34 and an output 35. The comparator unit 3 is implemented according to a circuit for comparing the instantaneous value of the signal at the signal input 34 with its average value at the same input 34. The signal input 34 of the comparator unit 3 is connected to signal output 33 of the microphone unit 2.

The comparator unit 3 contains a first comparator 9, the first input of which is the signal input 34 of the comparator unit 3. The second input 36 of the first comparator 9 is connected to the signal input 34 of the comparator unit 3 through a filter divider 10. The output of the first comparator 9 is the signal output 35 of the comparator unit 3 , and is connected by the first feedback 11 to the first input 34 of the first comparator 9.

According to a preferred embodiment, the output stage of the first comparator 9 is made with an open collector, the first input of the first comparator 9 is positive, and the second input 36 is negative (Fig. 2). In this case, the first feedback 11 is a capacitive positive feedback 11. In this case, the filter divider 10 is made in the form of a voltage divider built on the first 12 and second 13 impedances, connected in series to the signal input 34 of the comparator 3 with its power output. In parallel with the second resistance 13, a capacitance 14 is connected.

The delay unit 4 is designed to increase the duration of the active level of the control signal generated by the comparator unit 3. The delay unit 4 is equipped with a power input and output, as well as a signal input 37 and an output 38. The signal input 37 of the delay unit 4 is connected to the signal output 35 of the comparator 3.

According to a preferred embodiment, the delay unit 4 (Fig. 3) is made in the form of a series circuit of delay resistance 15 and delay capacity 16 connected between the input and output of the power of delay unit 4. The connection point of the delay resistance 15 and delay capacity 16 is a signal input 37 and simultaneously signal output 38 of the delay unit 4.

The hysteresis block 5 is designed to form a lag (delay) of the edges of the control signal relative to one another. The hysteresis unit 5 is equipped with a power input and output, as well as signal input 39 and output. The signal input 39 of the hysteresis unit 5 is connected to the signal output 38 of the delay unit 4. The signal output of the hysteresis unit 5 is the control output 32 of the inventive acoustic control unit 1.

The hysteresis unit 5 contains a second comparator 17, the first input of which is the signal input 39 of the hysteresis unit 5. The second input 40 of the second comparator 17 is connected to the output of the reference voltage source 18. The output of the second comparator 17 is the signal output 32 of the hysteresis unit 5, and is connected by a second feedback 19 with the second input 40 of the second comparator 17.

According to a preferred embodiment, the first input of the second comparator 17 is positive, and the second input 40 is negative (Fig. 4). In this case, the second feedback 19 is an active negative feedback and is made in the form of a resistance 19. In this case, the reference voltage source 18 is made in the form of a voltage divider built on the third 20 and fourth 21 resistances, sequentially connecting the input and output of the hysteresis unit 5.

The acoustic control unit may also contain a power source 22, and a power switch 23 (figure 5). The control output 32 is then connected to the control input of the power switch 23, and the control unit is provided with a power input 41 and an output 42, which simultaneously are the power input and output of the power switch 23. The input of the power supply 22 in this case is the power input 30 of the inventive control unit 1 and the supply voltage from the power output is supplied to the power inputs of the microphone unit 2, the comparator unit 3, the delay unit 4, and the hysteresis unit 5.

The power source may be linear (Fig.6).

The power switch can be made in the form of a field effect transistor.

When using the acoustic control unit 1, its input 30 and output 31 of the power supply are connected to a power source (Fig. 7). The control output 32 is connected to the control input of the power switch 23, the power circuit of which is connected in series with the load 24, for example, lighting.

The implementation of the structural elements of the claimed utility model is not limited to the above examples.

Work description.

When the acoustic control unit 1 is operating, an analog signal is generated at the output of the microphone unit 33, which corresponds to the acoustic effect on the microphone 7. In the comparator unit 3, this signal is continuously compared with its shifted average value. With a significant acoustic impact on the microphone, in which the control unit must generate an active control level of the signal, the instantaneous value of the signal at the first input 34 of the first comparator 9 goes over the potential boundary defined by its offset average value at the second signal input 36, and the comparator 9 sets the active level to its signal output 33.

Thanks to the first feedback 11, the signal at the output of the comparator 9 is kept active for the entire time set by the delay unit 4 after the disappearance of the acoustic effect on the microphone 7.

Getting to the signal input 39 of the hysteresis unit 5, the control signal is compared in the second comparator 17 with the reference signal generated by the corresponding source 18. If the control signal is inactive, the signal at the output of the second comparator 17 is also inactive. If the control signal at the signal input 39 of the second comparator 17 crosses the potential boundary specified by the source 18 at the second signal input 40, then the signal level at the output 32 of the second comparator 17 becomes active. In this case, thanks to the second feedback 19, the signal at the second input 40 of the second comparator 17 is shifted away from the current value of the signal at the first input 39, which provides the necessary control hysteresis in the inventive acoustic control unit 1.

In the inventive acoustic control unit, the claimed technical result: "improving the accuracy of setting the response level" is achieved due to the fact that the control unit contains a microphone unit, a delay unit, a hysteresis unit with a reference voltage source. In this case, the microphone unit contains a serial circuit of the power and microphone impedances, the connection point of which through the capacitance is connected to the first input of the first comparator. In this case, the first input of the first comparator is connected through a filter divider to the second input of the first comparator, and through the first feedback is connected to the output of the first comparator. The output of the first comparator is also connected to the signal input of the delay unit, and the signal output of the delay unit is connected to the signal input of the hysteresis unit. In this case, the hysteresis unit contains a second comparator, the first input of which is the signal input of the hysteresis unit, and the second input of which is connected to the reference voltage source and connected to the output of the second comparator through the second feedback.

The claimed technical result: "reduction of material consumption" is achieved due to the fact that the hysteresis unit contains a second comparator, the first input of which is the signal input of the hysteresis unit, and the second input of which is connected to the reference voltage source and connected to the output of the second comparator through the second feedback.

Industrial applicability.

The authors of the utility model made a prototype of the claimed utility model, the tests of which confirmed the achievement of the technical result.

The inventive acoustic control unit is implemented using industrially produced devices and materials, can be manufactured at any enterprise in the electronics industry and will find wide application in the field of control of electrical circuits, used, in particular, in lighting.

INFORMATION SOURCES.

1. RF patent for utility model No. 99901, IPC H01L 33/00, 2010

Claims (6)

1. The acoustic control unit, comprising a microphone unit with a microphone, a delay unit, a hysteresis unit containing a reference voltage source, while the signal output of the delay unit is connected to the signal input of the hysteresis unit, characterized in that the microphone unit contains a serial power supply and microphone resistance circuit, the connection point of which through the capacitance is connected to the first input of the first comparator, while the first input of the first comparator is connected through the filter divider to the second input of the first comparator, and as a result, the first feedback is connected to the output of the first comparator, while the output of the first comparator is also connected to the signal input of the delay unit, while the hysteresis unit contains a second comparator, the first input of which is the signal input of the hysteresis unit, and the second input of which is connected to the reference voltage source and through the second feedback connected to the output of the second comparator. 2. The control unit according to claim 1, characterized in that the output stage of the first comparator is made with an open collector, the first input of the first comparator is positive and the second input is negative, while the first feedback is capacitive positive feedback, while the filter divider made in the form of a voltage divider built on the first and second resistances, a filter capacitance is connected in parallel with the second resistance. 3. The control unit according to claim 1, characterized in that the delay unit is made in the form of a series circuit of delay resistance and delay capacitance, the connection point of which is simultaneously the signal input and output of the delay unit. 4. The control unit according to claim 1, characterized in that the first input of the second comparator is positive and the second input is negative, while the second feedback is active negative feedback, while the voltage reference is made in the form of a voltage divider. 5. The control unit according to claim 1, characterized in that it further comprises a power source, the output of which is connected to the power resistance, as well as to the power inputs of the delay unit and the hysteresis unit. 6. The control unit according to claim 1, characterized in that it further comprises a power switch, the control input of which is connected to the output of the second comparator.