KR101117529B1 - Integrator circuit of wireless ir receiver, wireless ir receiver comprising the same integrator circuit and method for controlling a integration signal - Google Patents

Abstract

The present invention relates to an integrated circuit of a wireless infrared receiver, a wireless infrared receiver including the integrated circuit, and an integrated signal adjusting method. An integrated signal output from an integrated circuit by controlling an amount of current flowing through the integrated circuit of an infrared receiver through a fusing circuit. An integrated circuit of a wireless infrared receiver which adjusts a rising time and a falling time of a wireless infrared receiver, a wireless infrared receiver including the integrated circuit, and an integrated signal adjusting method.

Description

INTEGRATOR CIRCUIT OF WIRELESS IR RECEIVER, WIRELESS IR RECEIVER COMPRISING THE SAME INTEGRATOR CIRCUIT AND METHOD FOR CONTROLLING A INTEGRATION SIGNAL}

The present invention relates to an integrated circuit of a wireless infrared receiver, a wireless infrared receiver including the integrated circuit, and an integrated signal adjusting method. An integrated signal output from an integrated circuit by controlling an amount of current flowing through the integrated circuit of an infrared receiver through a fusing circuit. An integrated circuit of a wireless infrared receiver which adjusts a rising time and a falling time of a wireless infrared receiver, a wireless infrared receiver including the integrated circuit, and an integrated signal adjusting method.

The wireless infrared receiver undergoes an electrical die sorting (EDS) test to select defective products or chips before shipping them to the product after wafer processing.

At this time, the operation characteristics of the respective internal circuits are verified. In particular, the wireless infrared receiver must pass only this specific frequency to distinguish the infrared data signal modulated at a specific frequency from other noise signals. Will be tested.

An object of the present invention is to improve the integrating circuit of the wireless infrared receiver to adjust the rising and falling time of the integrating circuit to solve the noise problem, to solve the code loss problem, to prevent the aggregation of signals, to reach the signal An integrated circuit of a wireless infrared receiver capable of improving distance, a wireless infrared receiver including the integrated circuit, and an integrated signal adjusting method are provided.

According to an aspect of the present invention, there is provided an integrated circuit for integrating and outputting a data signal according to an infrared signal received from a wireless infrared receiver, wherein at least one charging constant current source and a discharge constant current source are switched in a fusing circuit. It is selectively operated by the signal to change the amount of current in the circuit to charge or discharge the internal capacitor to adjust the rising time (falling time) and falling time (Falling time) of the output signal output through the corresponding capacitor Provide an integral circuit.

Preferably, the integrating circuit comprises: at least one charging constant current source having one terminal connected to a power supply voltage and the other terminal connected to a common terminal; At least one charging switch connected between the charging constant current source and the common terminal to be opened and closed by a switching signal of the fusing circuit; At least one discharge constant current source having one terminal connected to a ground voltage and the other terminal connected to a common terminal; At least one discharge switch connected between the discharge constant current source and the common terminal to be opened and closed by a switching signal of the fusing circuit; A capacitor having one terminal connected to the common terminal and the other terminal connected to a ground power source, the charging and discharging being adjusted by selective operation of the charging constant current source and the discharge constant current source; Characterized in that it comprises a.

On the other hand, according to another aspect of the invention, the integration circuit for integrating and outputting the data signal according to the received infrared signal; And a fusing circuit for applying a switching signal to the integrating circuit. The integrated circuit may include at least one charging constant current source and a discharge constant current source that are selectively operated by a switching signal of a fusing circuit to change or change the amount of current in the circuit, thereby charging or discharging an internal capacitor and outputting the corresponding capacitor. The present invention provides a wireless infrared receiver which adjusts a rising time and a falling time of an output signal.

Preferably, the integrating circuit comprises: at least one charging constant current source having one terminal connected to a power supply voltage and the other terminal connected to a common terminal; At least one charging switch connected between the charging constant current source and the common terminal to be opened and closed by a switching signal of the fusing circuit; At least one discharge constant current source having one terminal connected to a ground voltage and the other terminal connected to a common terminal; At least one discharge switch connected between the discharge constant current source and the common terminal to be opened and closed by a switching signal of the fusing circuit; A capacitor having one terminal connected to the common terminal and the other terminal connected to a ground power source, the charging and discharging being adjusted by selective operation of the charging constant current source and the discharge constant current source; Characterized in that it comprises a.

More preferably, the fusing circuit includes: a fusing resistor having one terminal connected to a ground voltage; A fusing pad connected to the other terminal of the fusing resistor; And a constant current source having one end connected to a common terminal of the fusing pad and the fusing resistor and the other terminal connected to a power supply voltage. And applying a voltage or current from the outside to the fusing pad to generate a high or low signal through the common terminal to apply a switching signal to the integrating circuit.

More preferably, the photodiode for receiving an infrared signal; A current voltage converter converting the current signal detected by the photodiode into a voltage signal and outputting the converted voltage signal; An amplifier stage for receiving the voltage signal output from the current voltage converter and adjusting and amplifying the magnitude of the signal voltage to a desired signal level by automatic gain control of a variable gain amplifier; A band pass filter for outputting a BPF signal passing only a carrier frequency signal of an infrared signal from the signal output through the amplifier stage; A peak signal detector for detecting a peak signal in the BPF signal filtered through the band pass filter; An automatic gain adjusting unit which receives a peak signal of the peak signal detector and adjusts a gain of the variable gain amplifier; A threshold adjuster for outputting a threshold adjustment signal using a peak signal and a reference signal output from the peak signal detector; A comparator for comparing a threshold control signal output from the threshold controller with a BPF signal output from the band pass filter and outputting a comparison signal; The integrated circuit further integrates the comparison signal output from the comparator and outputs the integrated signal, and the output of the integrated circuit is output through the Schmitt trigger circuit to generate a control signal.

On the other hand, according to another aspect of the invention, (a) applying a switching signal to the integration circuit through the fusing circuit; (b) selectively opening or closing at least one charge switch and a discharge switch according to the switching signal; (c) operating the at least one charging constant current source and the discharge constant current source according to the opening and closing operations of the charging switch and the discharge switch to change the amount of current in the circuit; And (d) adjusting a rising time and a falling time of an output signal output through the capacitor by charging or discharging the internal capacitor according to a change in the amount of current in the circuit. It provides an integrated signal adjustment method comprising a.

According to the present invention, by adjusting the amount of current flowing through the integrating circuit of the infrared receiver through the fusing circuit to adjust the rising time and falling time of the integrated signal output from the integrating circuit to adjust the pulse width of the signal There is an effect that can be adjusted.

Specifically, the fusing circuit may slowly adjust the rising time of the integrated signal output from the integrating circuit to remove unwanted noise components, and the wireless infrared receiver may be immune to noise.

In addition, through the fusing circuit, the polling time of the integrated signal output from the integrating circuit may be adjusted slowly to prevent code loss and to increase the reliability of the wireless infrared receiver.

In addition, through the fusing circuit, it is possible to quickly adjust the polling time of the integrated signal output from the integrating circuit, thereby preventing the aggregation of signals and increasing the reliability of the wireless infrared receiver.

In addition, the fusing circuit can quickly adjust the rising time of the integrated signal output from the integrating circuit to improve the reach of the signal and increase the performance and reliability of the wireless infrared receiver.

In addition, it has the effect of increasing the performance and reliability of the wireless infrared receiver as a whole to achieve a yield.

1 is a block diagram showing the configuration of a wireless infrared receiver to which the present invention is applied.
Figure 2 is a waveform diagram of the signals output from each configuration of the wireless infrared receiver to which the present invention is applied.
3 is a circuit diagram of a fusing circuit and an integrated circuit to which the present invention is applied.
4 is a waveform diagram showing an example of an integrated signal output from an integration circuit to which the present invention is applied;
Fig. 5 is a waveform diagram of signals output from respective components of the wireless infrared receiver of the present invention for explaining the solution of the noise problem.
Fig. 6 is a waveform diagram of signals output from each component of the wireless infrared receiver of the present invention for explaining the solution of the code loss problem.
7 is a waveform diagram of signals output from each configuration of the wireless infrared receiver of the present invention for explaining the solution of the signal aggregation problem.
8 is a waveform diagram of signals output from each configuration of the wireless infrared receiver of the present invention for explaining the solution of the reach problem.

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

1 is a block diagram showing a configuration of a wireless infrared receiver to which the present invention is applied, and FIG. 2 is a waveform diagram of signals output from each configuration of the wireless infrared receiver to which the present invention is applied.

As shown in FIG. 1, the wireless infrared receiver includes a photodiode 10, a current voltage converter 20, an amplifier 30, a band pass filter 40, a shaping unit 50, and an automatic gain adjusting unit 70. , Fusing circuit 80 and Schmitt trigger circuit 90.

The photodiode 10 is configured to receive a signal transmitted from a remote controller and the like, and converts the received signal in the form of light into the form of a current.

The current voltage converter 20 converts a current resistor detected by the photodiode 10 into a voltage signal by connecting a conversion resistor R1 to the photodiode 10. And a voltage signal is output through the common terminal of the photodiode 10.

The amplifier stage 30 serves to amplify the voltage signal output from the current voltage converter 20, the first amplifier 31 to amplify the voltage signal output through the current voltage changer 20 A variable gain amplifier 32 designed to adjust gain by adjusting a signal amplified once through the first amplifier 31 to a gain control current or a gain control voltage of an automatic gain control unit 70 to be described later; And a second amplifier 33 which amplifies the signal output through the variable gain amplifier 32 once again.

The band pass filter 40 filters only a carrier frequency signal of the infrared signal from the signal output through the amplifying stage 30. 2 illustrates a BPF signal output from the band pass filter 40. Preferably, the band pass filter 40 filters only the frequency signal of the 38 KHz band used in TV, DVD, and the like.

The shaping unit 50 includes a peak signal detector 51 for detecting a peak detection signal from a BPF signal filtered through the band pass filter 40, and the peak signal detector 51. A threshold controller 52 for outputting a threshold control signal (ATC) using a peak detection signal and a reference signal Vref output from the threshold controller 52 and the threshold controller 52. The comparator 53 outputs a comparison signal Comp Out by comparing the output ATC signal and the BPF signal output from the band pass filter 40, and the comparator 53. And an integration circuit 60 for integrating the output comparison signal Comp Out and outputting an integration signal Int Out.

In this case, the reference signal Vref input to the threshold controller 52 may be determined as a voltage slightly higher than the average voltage of the band pass filter 40 output.

On the other hand, the input signal coming into the infrared receiver from the outside is not only an infrared component, but also unwanted unwanted light, such as fluorescent lamps or sunlight, is usually input, such disturbance light is considered to be a noise component because they are not intended by the designer. .

Here, the output of the peak signal detector 51 is transmitted to the automatic gain control unit 70. When the signal input to the automatic gain control unit 70 to remove noise is noise, the variable gain amplifier ( The automatic gain control unit 70 operates in a direction in which the gain of 32 is decreased. In contrast, when the input signal is a normal signal instead of noise, the corresponding automatic gain increases so that the gain of the variable gain amplifier 32 increases. The adjusting unit 70 is operated.

In addition, the output of the integrating circuit 60 (Int Out) is output through the Schmitt trigger circuit 90 (Data Out) to be delivered to the output circuit portion or directly to the output.

On the other hand, the integrator circuit 60 of the shaping unit 50 is connected to the fusing circuit 80, the output signal (Int Out) of the integrator circuit 60 by the corresponding fusing circuit 80 Rising time and falling time (Falling time) of the can be adjusted.

3 is a circuit diagram of a fusing circuit and an integration circuit to which the present invention is applied.

The fusing circuit 80 includes a fusing resistor R _F , a constant current source I _S , and a fusing pad 81 therein. Fusing resistor (R _F) is to be a terminal is connected to the ground voltage, the other terminal of said fusing resistor (R _F) connected to the fusing pad 81. One terminal of the constant current source I _S is connected to the common terminal of the fusing pad 81 and the fusing resistor R _F , and the other terminal of the constant current source I _S is connected to a power supply voltage. Here, the fusing pad 81 applies a voltage or current for trimming the fusing resistor R _F.

In the fusing circuit 80, the constant current source I _S generates a constant current to flow a constant current, and externally applies a voltage or current to the fusing pad 81 to provide the constant current source I _S and the fusing pad. A signal of high or low is generated through the common terminal of the 81 and the fusing resistor R _F , and a switching signal is applied to the integrating circuit 60 through a decoder (not shown).

On the other hand, the integrating circuit 60 has a plurality of switches (SW _1R , SW _2R , SW _3R , SW _1F , SW _2F , SW _3F ) that is turned on or off in accordance with the switching signal applied from the fusing circuit 80 A plurality of constant current sources I _1R , I _2R , I _3R , I _1F , I _2F , and I _3F flow through the corresponding switches, and these constant current sources I _1R , I _2R , I _3R , I A capacitor C charged or discharged by _1F , I _2F , I _3F ) is provided.

Each of the first charging constant current source I _1R , the second charging constant current source I _2R , and the third charging constant current source I _3R for adjusting the rising time of the integration signal Int Out is one terminal. Is connected to the supply voltage and the other terminal is connected to the common terminal to allow a constant current to flow through the circuit. One terminal of the capacitor C charged by the current is provided at a common terminal of the first charging constant current source I _1R , the second charging constant current source I _2R , and the third charging constant current source I _3R . The other terminal of the capacitor C is connected to the ground voltage.

The first charging constant current source I _1R , the second charging constant current source I _2R , and the third charging constant current source I _3R are respectively connected to each other by a switching signal of the fusing circuit 80. The controlled first charging switch SW _1R , the second charging switch SW _1R and the third charging switch SW _1R are connected to each other.

Therefore, the integrating circuit 60 may be opened and closed by selectively opening and closing the first charging switch SW _1R , the second charging switch SW _1R , and the third charging switch SW _1R controlled by the switching signal of the fusing circuit 80. A current amount of the first charging constant current source (I _1R ), the second charging constant current source (I _2R ) and the third charging constant current source (I _3R ) is selectively charged to the capacitor (C). As a result, the rising time of the integral signal Int Out may be adjusted.

Meanwhile, the first discharge constant current source I _1F , the second discharge constant current source I _2F , and the third discharge constant current source I _3F for adjusting the falling time of the integral signal Int Out are respectively. One terminal is connected to the ground voltage and the other terminal is connected to the common terminal to allow a constant current to flow through the circuit. The common terminals of the first discharge constant current source I _1F , the second discharge constant current source I _2F , and the third discharge constant current source I _3F may include the first charge constant current source I _1R and the second charge. It is connected to the common terminal of the constant current source I _2R and the third charging constant current source I _3R and the capacitor C.

The first discharge constant current source I _1F , the second discharge constant current source I _2F , and the third discharge constant current source I _3F and the common terminal are respectively switched by the switching signal of the fusing circuit 80. The controlled first discharge switch SW _1F , second discharge switch SW _1F and third discharge switch SW _1F are respectively connected.

Accordingly, the integrating circuit 60 may be opened and closed by selectively opening and closing the first discharge switch SW _1F , the second discharge switch SW _1F , and the third discharge switch SW _1F controlled by the switching signal of the fusing circuit 80. To selectively discharge the capacitor C by the current of the first discharge constant current source I _1F , the second discharge constant current source I _2F , and the third discharge constant current source I _3F . As a result, the falling time of the integrated signal (Int Out) can be adjusted.

As a result, the switches SW _1R , SW _2R , SW _3R , SW _1F , SW _2F , SW _3F are selectively opened and closed by a switching signal applied from the fusing circuit 80, and as a result, the integration circuit 60 By changing the current amount of), the rising time and the falling time of the output integral signal Int Out are adjusted.

In the above description, the switches SW _1R , SW _2R , SW _3R , SW _1F , SW _2F , and SW _3F may be selectively opened and closed by a switching signal applied from the fusing circuit 90. _1R , SW _2R , SW _3R , SW _1F , SW _2F , SW _3F ) and the number of constant current sources (I _1R , I _2R , I _3R , I _1F , I _2F , I _3F ) operated thereby. And of course not limited to the six illustrated in the drawings.

The integrating circuit 60 has a structure in which the voltage V of the capacitor C is charged or discharged by the following equation (1).

는 시간에 대한 전류의 적분(총합)을 의미한다. 여기에서 전류량을 조절하게 되면 라이징 타임과 폴링 타임을 조절할 수 있게 된다. In Equation 1, C is the capacity of the capacitor,

Is the integral (total) of the current against time. Adjusting the amount of current here will allow you to adjust the rise time and the polling time.

An example of an integrated signal Int Out output from the integration circuit 60 is illustrated in FIG. 4.

Referring to FIG. 4, in the integral signal (Int Out) output from the integrating circuit 60, ① is a signal for increasing the rising time by adjusting the amount of current flowing through the integrating circuit 60, and ② is for slowing the rising time. It is a signal. In the integral signal (Int Out) output from the integrating circuit 60, ③ is a signal for slowing the polling time, and ④ is a signal for accelerating the polling time.

One of the important objects of the present invention is to solve the noise problem by adjusting the pulse width by adjusting the rising time or the falling time in the integrated signal (Int Out) output from the integration circuit 60, and the code It solves the loss problem, prevents signal aggregation and improves the signal's reach.

Hereinafter, by using the fusing circuit 80 and the integrating circuit 60 of the present invention with reference to the drawings to adjust the rise time and polling time to solve the noise problem, code loss problem, signal aggregation problem, reach problem Look specifically at the process.

5 is a waveform diagram of signals output from respective components of the wireless infrared receiver of the present invention for explaining the solution of the noise problem.

5 illustrates a case where the rising time of the integral signal Int Out output from the integrating circuit 60 is shortened. If the rising time is faster in the integral signal (Int Out) output from the integrating circuit (60), unwanted signals are detected by the Schmitt trigger circuit (90) that outputs data as in (2) so that data of noise component Will be output.

In this case, the rising time of the integral signal Int Out output from the integrating circuit 60 is slowly adjusted through the fusing circuit 80 so that the data of the noise component is not output as shown in?. This eliminates unwanted noise components and makes the wireless infrared receiver immune to noise.

Next, Figure 6 is a waveform diagram of the signals output from each configuration of the wireless infrared receiver of the present invention for explaining the solution of the code loss problem.

FIG. 6 illustrates a phenomenon in which a polling time is increased in an integrated signal Int Out output from the integration circuit 60. That is, if the polling time is faster in the integral signal (Int Out) output from the integrating circuit 60, an unwanted signal is detected by the Schmitt trigger circuit 90 as shown in (2) and code loss (Code-) as shown in the figure. missing).

In this case, by slowly adjusting the polling time of the integral signal Int Out output from the integrating circuit 60 through the fusing circuit 80, the code loss can be adjusted such that ① does not occur. This prevents code loss and increases the reliability of the wireless infrared receiver.

Next, Figure 7 is a waveform diagram of the signals output from each configuration of the wireless infrared receiver of the present invention for explaining the solution of the signal aggregation problem.

FIG. 7 illustrates a case in which a polling time is slow in an integrated signal Int Out output from the integration circuit 60. That is, if the polling time is slow in the integral signal (Int Out) output from the integrating circuit 60, the desired signal does not come out as shown in (2) and the phenomenon of signal aggregation occurs.

In order to compensate for this, the polling time of the integrated signal Int Out output from the integrating circuit 60 can be quickly adjusted through the fusing circuit 80 so that the desired signal can be displayed as shown in ①. This prevents signal aggregation and increases the reliability of the wireless infrared receiver.

Next, Figure 8 is a waveform diagram of the signals output from each configuration of the wireless infrared receiver of the present invention for explaining the solution of the reach problem.

FIG. 8 illustrates a case where the rising time is slow in the integral signal Int Out output from the integration circuit 60. In fact, when you send 20 signals over a long distance, there is a rough reduction in where you actually receive them. That is, if 10 waveforms enter the wireless infrared receiver as shown in FIG. 8, the rising time becomes slow in the integral signal Int Out output from the integrating circuit 60, resulting in an incorrect signal as shown in ②. In this case, there is a distance problem in the performance of the wireless infrared receiver.

In order to compensate for this, the rising time of the integral signal (Int Out) output from the integrating circuit 60 through the fusing circuit 80 can be quickly adjusted to obtain a desired signal at a desired distance as in ①. This improves signal reach and increases the performance and reliability of wireless infrared receivers.

As described above, an optimal embodiment has been disclosed in the drawings and specification. Although specific terms have been used herein, they are used only for the purpose of describing the present invention and are not used to limit the scope of the present invention as defined in the meaning or claims. Therefore, those skilled in the art will appreciate that various modifications and equivalent embodiments are possible without departing from the scope of the present invention. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

10: photodiode 20: current voltage converter
30: amplification stage 31: first amplifier
32: variable gain amplifier 33: second amplifier
40: band pass filter 50: shaping part
51: peak signal detector 52: threshold adjuster
53: comparator 60: integral circuit
70: automatic gain control unit 80: fusing circuit
90: Schmitt trigger circuit

Claims (7)

An integrated circuit for integrating and outputting a data signal according to an infrared signal received by a wireless infrared receiver,
At least one charging constant current source and a discharge constant current source are selectively operated by a switching signal of the fusing circuit to change the amount of current in the circuit, thereby charging or discharging the internal capacitor so that the rising time of the output signal output through the corresponding capacitor ) And a falling time.
The method of claim 1,
The integrating circuit is
At least one charging constant current source having one terminal connected to a power supply voltage and the other terminal connected to a common terminal;
At least one charging switch connected between the charging constant current source and the common terminal to be opened and closed by a switching signal of the fusing circuit;
At least one discharge constant current source having one terminal connected to a ground voltage and the other terminal connected to a common terminal;
At least one discharge switch connected between the discharge constant current source and the common terminal to be opened and closed by a switching signal of the fusing circuit; And
A capacitor having one terminal connected to the common terminal and the other terminal connected to a ground power source, the charging and discharging being adjusted by selective operation of the charging constant current source and the discharge constant current source; Integrating circuit comprising a.
An integrating circuit for integrating and outputting a data signal according to the received infrared signal; And
A fusing circuit for applying a switching signal to the integrating circuit; Including,
The integrating circuit may be configured such that at least one charging constant current source and a discharge constant current source are selectively operated by a switching signal of a fusing circuit to change the amount of current in the circuit, thereby charging or discharging an internal capacitor to rise the output signal output through the corresponding capacitor. Wireless infrared receiver, characterized in that the adjustment of the rising time (Rising time) and falling time (Falling time).
The method of claim 3,
The integrating circuit is
At least one charging constant current source having one terminal connected to a power supply voltage and the other terminal connected to a common terminal;
At least one charging switch connected between the charging constant current source and the common terminal to be opened and closed by a switching signal of the fusing circuit;
At least one discharge constant current source having one terminal connected to a ground voltage and the other terminal connected to a common terminal;
At least one discharge switch connected between the discharge constant current source and the common terminal to be opened and closed by a switching signal of the fusing circuit; And
A capacitor having one terminal connected to the common terminal and the other terminal connected to a ground power source, the charging and discharging being adjusted by selective operation of the charging constant current source and the discharge constant current source; Wireless infrared receiver comprising a. The method of claim 3,
The fusing circuit,
A fusing resistor having one terminal connected to a ground voltage;
A fusing pad connected to the other terminal of the fusing resistor; And
A constant current source having one end connected to a common terminal of the fusing pad and the fusing resistor and another terminal connected to a power supply voltage; Including;
And applying a switching signal to the integrating circuit by applying a voltage or current to the fusing pad from the outside to generate a high or low signal through the common terminal.
The method of claim 3,
A photodiode receiving an infrared signal;
A current voltage converter converting the current signal detected by the photodiode into a voltage signal and outputting the converted voltage signal;
An amplifier stage for receiving the voltage signal output from the current voltage converter and adjusting and amplifying the magnitude of the signal voltage to a desired signal level by automatic gain control of a variable gain amplifier;
A band pass filter for outputting a BPF signal passing only a carrier frequency signal of an infrared signal from the signal output through the amplifier stage;
A peak signal detector for detecting a peak signal in the BPF signal filtered through the band pass filter;
An automatic gain adjusting unit which receives a peak signal of the peak signal detector and adjusts a gain of the variable gain amplifier;
A threshold adjuster for outputting a threshold adjustment signal using a peak signal and a reference signal output from the peak signal detector;
A comparator for comparing a threshold control signal output from the threshold controller with a BPF signal output from the band pass filter and outputting a comparison signal; More,
And the integrating circuit integrates the comparison signal output from the comparator and outputs the integral signal, and the output of the integrating circuit is output through the Schmitt trigger circuit to generate a control signal.
(a) applying a switching signal to the integrating circuit through the fusing circuit;
(b) selectively opening or closing at least one charge switch and a discharge switch according to the switching signal;
(c) operating the at least one charging constant current source and the discharge constant current source according to the opening and closing operations of the charging switch and the discharge switch to change the amount of current in the circuit; And
(d) adjusting a rising time and a falling time of an output signal output through the capacitor by charging or discharging the internal capacitor according to a change in the amount of current in the circuit; Integrated signal adjusting method comprising a.

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