KR930004616Y1 - Sound generating circuit for toy - Google Patents

Abstract

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Description

Sound generation circuit for toy

1 is a block diagram of a sound generating circuit for toys according to the present invention.

Figure 2 is a circuit diagram showing a preferred embodiment of the toy sound generating circuit according to the present invention.

3 is a timing chart of each part of FIG.

* Explanation of symbols for main parts of the drawings

1: analog circuit part 2: digital circuit means

3: power supply circuit section 10: microphone

12: vibration sensor 14: detection circuit means

16: voice synthesis circuit means 18: voice output circuit means

20: speaker 22: volume control means

24: control circuit means 26: first power supply circuit means

28: second power supply circuit means 30: the battery

SW1: Power switch SW2: Reset switch

The present invention relates to a sound generating circuit for toys, and more particularly to a sound generating circuit for toys that can be generated more lively and power consumption.

In recent years, due to the remarkable development of semiconductor technology, more vibrant electronic toys and the like are commercially available. In particular, with the development of memory devices and voice processing technologies, voice synthesizer IC chips, which are cheaper and can store various kinds of sounds, have been shipped. A sound generating toy using such a voice synthesis integrated circuit chip is a circuit driving power source autonomously, and a circuit device is built in the toy body such that the reproduced voice is repeatedly output by driving a speaker in response to an external input.

However, the conventional sound generating toys repeatedly generate a sound signal reproduced and output from the voice synthesis integrated circuit chip only at a certain volume, so that the number of times the use increases, the first curiosity is halved and the children easily get tired of it. There was this. In particular, toys that generate sound in response to the crying of infants are recently marketed in order to soothe infants up to 2 years of age on behalf of their parents. Has the disadvantage of falling in proportion to the number of uses.

In addition, since these sound-generating toys usually have a built-in battery as a power supply means, it is pointed out that the batteries need to be frequently replaced unless the power consumption of the battery is minimized.

An object of the present invention is to provide a sound generating circuit for toys that can generate more lively sound by allowing the volume of the generated sound to be automatically adjusted in a wave form to solve the problems of the prior art as described above.

Another object of the present invention is to provide a sound generator circuit for toys that can reduce the power consumption of the battery by automatically turning off the power of the analog circuit portion that consumes a lot of power when there is no external input for a certain time.

In order to achieve the above object, the present invention is a toy sound generating circuit for reproducing and outputting sound stored in response to shaking or noise, the vibration sensor for receiving the shake and the microphone for receiving the shake Or detection circuit means for generating a detection signal when noise is received; Voice synthesis circuit means for storing at least one type of sound as digital data, reproducing the digital data as an analog voice signal, and repeatedly outputting the digital data; Voice output circuit means for receiving the voice signal generated from the voice synthesis circuit means and driving a speaker; In response to the detection signal supplied from the detection circuit means, the volume of the audio output circuit means is controlled to be changed from the maximum level to the minimum level gradually and from the minimum level to the maximum level gradually through the volume adjusting means. In response to the control to change the type of the reproduced voice signal of the voice synthesis circuit means, and to generate a power control signal when the detection signal is not supplied for a predetermined time and to release the power off state in response to a reset switch. Control circuit means; First power supply circuit means for supplying constant voltage to the voice synthesis circuit means and the control circuit means by supplying a power voltage supplied from a battery through a power switch; And a second power supply circuit means for supplying a power supply voltage supplied from the battery to the detection circuit means and the audio output circuit means in response to a power control signal of the control circuit means. .

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram of the present invention, which is largely divided into an analog circuit portion 1, a digital circuit portion 2, and a power supply circuit portion 3. The analog circuit portion includes a microphone 10, a vibration sensor 12, a detection circuit means 14, a speaker 20, a voice output circuit means 18 and a volume adjusting means 22. The digital circuit portion 2 has a voice synthesis circuit means 16 and a control circuit means 24. The power supply circuit portion 3 comprises first and second power supply circuit means 26, 28 and a battery 30. SW1 is the power switch and SW2 is the reset switch.

A detailed circuit diagram of the present invention will be described with reference to FIG. 2.

The detection circuit means 14 receives the external noise, for example, the crying sound of the infant, into the microphone 10 and inputs the received signal to one terminal of the associating amplifier U1 via the coupling capacitor C1 and the resistor R2. The amplification ratio is amplified by the resistor R3 compared to the reference voltage signals supplied by the resistors R4 and R5 supplied to the other terminals of the associating amplifier U1, and then output through the diode D1. In addition, the detection circuit means 14 receives the shaking of the body by the vibration sensor 12 and inputs the received signal to the other terminal of the operational amplifier U2 via the coupling capacitor C2 and the resistor R7, Compared to the reference voltage signal supplied to one terminal of the amplifier U2, it is amplified by the amplification factor by the resistor R9 and then output through the diode D2. In addition, the detection circuit means 14 inputs the outputs of the diodes D1 and D2 to the other terminal of the operational amplifier U3 and compares them with the reference voltage signal supplied to the one terminal thereof to detect the detection signal for the external input. It occurs through the resistor R11.

The audio output circuit means 18 is composed of a low pass filter circuit composed of condensers C4 to C7 and resistors R13 to R15 and an amplifier U4, and the output of the amplifier U4 is passed through a coupling capacitor C8. The speaker 20 is supplied.

The volume adjusting means 22 is made by connecting the resistors R16 to R18 having different resistance values in parallel between one terminal of the amplifier U4 and the ground through the control circuit means 24.

The speech synthesis circuit means 16 is composed of a known speech synthesis integrated circuit chip (manufactured by Samsung Semiconductor KS 5912 ××). This KS 5912 ×× chip is an adaptive delta modulated LSI chip with 64Kbit mask ROM, 10bit D / A converter, etc., 4 kinds of sound can be selected, and the selected sound is repeatedly reproduced and output at 8 second intervals. In the present invention, the selection input terminal PH1 is grounded and the selection input terminal PH0 is connected to the control circuit means 24 so that two kinds of sounds can be selected. The output terminal OUT of the KS5912 ×× chip is connected to the input terminal of the audio output circuit means 18, and the start input terminal START is connected to the control circuit means 24 through the resistor R19, and the clock output terminal. CK is connected to the control circuit means 24.

The control circuit means 24 is a combination circuit consisting of a gate and a flip-flop and has input and output characteristics shown in FIG. That is, the control circuit means 24 is supplied with the 5V voltage supplied from the first power supply circuit means 26 to the power supply terminal V _DD and the input terminal PO is the reset signal at the initial supply of the 5V voltage. The output of the one-shot circuit composed of a resistor R20 and a capacitor C10 for generating a is supplied.

The reset switch SW2 is connected to both ends of the capacitor C10 of the one-shot circuit to reset the control circuit means 24. The detection signal supplied from the detection circuit means 14 is coupled to the input terminal P1 of the control circuit means 24. The input signal P2 of the control circuit means 24 couples the clock signal of the voice synthesis circuit means 16. The clock signal has repetitive output information of the audio reproduction output of the audio synthesis circuit means 16. That is, the low section of the clock signal is a section without audio output and the high section is a section where audio is output. In addition, the resistors R21 and R22 and the capacitor C11 are connected to the input terminals P3 to P5 of the control circuit means 24 to determine the time constant of the internal clock of the control circuit means 24.

Resistors R16, R17, and R18 of the volume adjusting means 22 are connected to the output terminals S0 to S2 of the control circuit means 24, respectively. These output terminals S0 to S2 are provided as drain electrodes of the open drain MOS transistor. Therefore, when the MOS transistor is turned on, the output terminals S0 to S2 are grounded.

Here, as shown in FIG. 3, the output terminals S0 to S2 are first output terminals S0 when the resistance value of the resistors R16 to R18 of the volume adjusting means 22 is determined as R16 > R17 > It goes low and the remaining output terminals S1 and S2 go into a high impedance state and are selected as the state of maximum volume. If noise is generated or the toy body is shaken, the detection signal D1 is inputted to the input terminal P1 of the control circuit means 24 and the output terminal S1 in response to the rising edge of the detection signal D1. Is low, output terminals S0 and S2 are in high impedance state, and then output terminals S2 are in low state and output terminals S0 and S2 are in high impedance state. This large R17 and R18 are selected. Therefore, the voice output V ₀ gradually decreases from the maximum volume to become the minimum volume (1 in FIG. 3). At the minimum volume state, the output state of the output terminal S3 of the control circuit means 24 goes from the low state to the high state. Since it is inverted, the second sound is selected and output from the first sound in the KS 5912xX chip.

After the second sound is selected, the output state of the output terminals S0 to S2 is sequentially changed, as described above, so that the volume is increased from minimum to maximum (2 in FIG. 3).

If the detection signal D1 is maintained continuously, the maximum volume state is maintained as it is, but at the falling edge of the detection signal D1, the volume becomes the minimum from the maximum again (3 in Fig. 3), and the first sound is selected from the second sound. The volume is adjusted from the minimum to the maximum (④ in FIG. 3). When the detection signal D2 is input again while maintaining the maximum volume, the operation as described above is repeated.

If the volume is increased from the rising edge of the detection signal in which the volume is changed from the maximum to the minimum volume, the volume is raised to the minimum volume at the rising edge of the detection signal in the process of changing from the minimum to the maximum volume. The falling edge of the detection signal during the volume change is similarly adjusted to the volume as described above. In the present invention, only three steps of the volume adjustment step are illustrated, but it should be noted that more or less than three steps are possible.

The output terminal S3 of the control circuit means 24 is connected to the selection input terminal PHO of the voice synthesis circuit means 16. When the signal for selecting the minimum volume is generated at the output terminals S0 to S2, the output terminal S3 generates an output signal in which its output state is reversed.

In the low state, the input signal of the select input terminals PHO and PH1 of the KS 5612 × X chip becomes “00” and the first sound is selected. In the high state, the first sound is “01” and the second sound is Will be chosen. The output terminal S4 of the control circuit means 24 is connected to the start input terminal START of the KS 5912 ×× chip to start the audio output of the KS 5912 ×× chip, and is the input terminal of the control circuit means 24. It is synchronized with the clock signal input to (P2).

The output terminal S5 of the control circuit means 24 is connected to the control input terminal of the second power supply circuit means 28. In this output terminal S5, when the detection signal supplied from the detection circuit means 14 is not supplied for a predetermined time, a power supply control signal that goes from a high state to a low state is generated. This power supply control signal goes from a low state to a high state when the control circuit means 24 is reset again by the reset switch SW2.

The first power supply circuit unit 26 converts the DC voltage supplied from the 9V battery 30 through the power switch SW1 into a constant voltage by the zener voltage of the zener diode ZD, thereby switching the voltage of 5V through the switching transistor Q1. The supply voltage V _DD is supplied to the digital circuit portion 2. The resistor R23 is a bias resistor and the capacitors C12 and C13 are smoothing capacitors.

The second power supply circuit means 28 is for supplying a supply voltage V _oc to the analog circuit portion 1 and is supplied in response to a power control signal supplied from the output terminal S5 of the control circuit means 24. The output of the voltage V _oc is controlled. That is, the DC voltage supplied from the 9V battery 30 through the switching SW1 is output through the switching transistor Q2, and the switching transistor Q2 is connected to its base electrode via the resistor R25. Is turned on at turn-on and turned off at turn-off. The switching transistor Q3 is connected to the output terminal S5 of the control circuit means 24 via a resistor R26 at its base electrode.

The operation and effects of the present invention configured as described above are as follows.

First, when the power switch SW1 is turned on, the supply voltage V _DD is supplied to the digital circuit portion 2 by the first power supply circuit means 26 so that the control circuit means 24 is initially reset and the second The supply voltage V _DD is supplied to the power supply circuit means 28 to the analog circuit portion 1, and the voice synthesis circuit means 16 is started by the control circuit means 24, and the output terminal OUT is provided to the output terminal OUT. One sound is selected and played back. At this time, the voice output circuit means 18 is adjusted to the maximum volume by the volume adjusting means 22 to filter and amplify the voice signal supplied from the voice synthesis circuit means 16 to drive the speaker 20. Therefore, the first sound generated by the speaker 20 is output at the maximum volume. In this state, when an external input, ie noise or body shake, the detection circuit means 14 generates a detection signal, and the control circuit means 24 inputs this detection signal to increase the volume at the rising edge of the detection signal. Gradually decreasing from the maximum to the minimum volume, the sound generated by the voice synthesis circuit means 16 is selected from the first sound to the second sound, and the selected second sound is gradually raised from the minimum volume to the maximum volume. The control circuit means 24 outputs the second sound at the maximum volume and gradually decreases the volume from the maximum to the minimum when the falling edge of the detection signal is input. When the minimum volume is reached, the sound generated by the voice synthesis circuit means 16 is selected from the second sound to the first sound, and the selected second sound is gradually raised from the minimum volume to the maximum volume.

In this way, whenever the detection signal is input, the volume of the voice signal generated automatically by the wave shape is automatically adjusted to the wave shape in response to the rising edge and the falling edge of the detection signal. May occur. In addition, by repeatedly outputting the first sound and the second sound whenever the volume is minimized, the initial curiosity can be maintained for a long time.

In addition, in the present invention, if there is no input of the detection signal for a predetermined time, the control circuit 24 generates a power control signal to cut off the supply of the supply voltage V _oc to the analog circuit portion 1 that consumes a lot of power. Because it can minimize the life of the battery 30 can be extended, even if used for a long time can reduce the user's hassle due to replacement of the battery (30).

Claims (1)

A toy sound generating circuit for reproducing and outputting a sound stored in response to a shake or a noise, comprising: a detection signal when a shake or noise is received by a vibration sensor for accepting the shake and a microphone for accepting the noise; Detection circuit means for generating; Voice synthesis circuit means for storing at least one type of sound as digital data, reproducing the digital data as an analog voice signal, and repeatedly outputting the digital data; Voice output circuit means for receiving the voice signal generated from the voice synthesis circuit means and driving a speaker; In response to the detection signal supplied from the detection circuit means, the volume of the audio output circuit means is controlled to be changed from the maximum level to the minimum level gradually and from the minimum level to the maximum level gradually through the volume adjusting means. In response to the control to change the type of the reproduced voice signal of the voice synthesis circuit means, and to generate a power control signal when the detection signal is not supplied for a predetermined time and to release the power off state in response to a reset switch. Control circuit means; First power supply circuit means for supplying constant voltage to the voice synthesis circuit means and the control circuit means by supplying a power voltage supplied from a battery through a power switch; And a second power supply circuit means for supplying a power supply voltage supplied from the battery to the detection circuit means and the audio output circuit means in response to a power control signal of the control circuit means. Sound generation circuit for toys.