KR100190846B1 - Amplitude detection device - Google Patents

Abstract

An amplitude detecting apparatus includes an amplitude detecting unit that receives an input signal having a predetermined amplitude from an external source and receives a feedback signal having a voltage of a predetermined level from another input terminal, A control means for comparing the two input signals and outputting a control signal in response to the compared result; a control means for receiving a voltage of a predetermined level from the outside, To the other input terminal of the control means, charger means for charging a voltage of a predetermined level outputted from the switching means, and switching means connected between the switching means and the charger means, And charger distribution means for distributing the charge that has been charred, wherein the switching means and the charger And outputs a value proportional to the amount of charge charged in the charger means by an output terminal connected between the distributing means. With such an apparatus, the accurate amplitude can be detected regardless of the amplitude of the input signal being changed. Since the value of the capacitor used is small, an amplitude detection circuit suitable for an integrated circuit can be realized.

Description

A Peak Detection Circuit

More particularly, the present invention relates to an amplitude detecting apparatus which receives a signal having a predetermined frequency from the outside and accurately detects the maximum value of the input signal (Vin) irrespective of the amplitude change of the input signal .

In general, digital data service networks use an equalizer circuit to compensate for transmission losses. The process of this equalization opportunity includes detecting the amplitude of the AC type input through the transmission line and detecting the maximum amplitude of the DC type and using the maximum amplitude value of the detected input signal to equalize the loss of the transmission line Lt; / RTI > Then, the equalizer compensates the loss of the signal in the transmission line according to the control value. Therefore, one of the important factors in the design of equalization opportunities is to accurately detect the amplitude of the input signal.

1A is a circuit diagram schematically showing a configuration of a conventional amplitude detecting device.

1A, a conventional amplitude detecting apparatus includes control means 10 for receiving a feedback signal having an input signal Vin and a predetermined level of voltage Vdd at two input terminals and outputting a predetermined control signal, In which a voltage (Vdd) of a predetermined level is applied from the outside and a voltage (Vdd) of a predetermined level applied from the outside is applied to the other input terminal of the control means in response to a control signal applied from the control means (20) and the other end of which is connected to the ground unit (16) to charge the voltage (Vdd) of a predetermined level outputted from the switching unit (20) A charger 30 connected between the output terminal of the switching means 20 and the charger 30 for outputting a voltage value proportional to the amount of charge charged in the charger 30; And a terminal 12. Here, the control means 10 is an OP-AMP that receives an input signal Vin to a non-inverting terminal and receives a feedback signal having a voltage Vdd of a predetermined level as an inverting terminal. The switching means 20 is connected to the switching means 20 through a switching means 20 such that the collector terminal is connected to the power supply portion 14 and the base terminal is connected to the output terminal of the control means 10 and the emitter terminal is connected to the other input terminal of the control means 10 It is a bipolar transistor. The charger means 30 is a capacitor whose one end is connected to the output terminal of the switching means 20 and the other end is connected to the grounding portion 16.

1B shows amplitude detection results of the amplitude detection apparatus having the above-described configuration.

Referring to FIG. 1B, the amplitude detection apparatus of the related art correctly detects the amplitude when the input signal has a larger amplitude than the signal inputted before, but the amplitude (B) of the input signal is smaller than the amplitude (A), the amplitude (B) of the current input signal is not detected and the amplitude (A) of the previous input signal is still detected. That is, when the input signal continuously increases, the maximum value of the amplitude can be accurately detected. However, when the amplitude of the input signal repeatedly increases or decreases or the input signal decreases, the amplitude of the input signal can not be detected.

Therefore, if an equalizer is designed using a conventional amplitude detecting device, if an input signal having a large amplitude instantaneously enters due to the surrounding environment or noise, an error occurs in the amplitude detection value of the input signal and the equalizer or the like is malfunctioned Problems arise.

FIG. 2A is a schematic circuit diagram of an amplitude detection apparatus that has been widely used to solve the above problems.

2A, the conventional amplitude detecting device is connected to an output terminal of the switching means 20 and the output terminal 12 at one end in a conventional amplitude detecting device having a configuration as shown in FIG. 1A And a current source 40 whose other end is connected to the grounding portion 16 is added. At this time, the current source 40 discharges a predetermined amount of charge, which has been charred to the charger 30, to the ground unit 16. [

According to such an apparatus, a predetermined amount of charge that is charred in charger means 30 is flowed to the grounding portion 16 through the current source 40, so that the potential of the output terminal is lowered constantly, Even an input signal having a smaller amplitude can be detected. Referring to FIG. 2B, the potential of the output signal Vout decreases steadily, and even an input signal having an amplitude D smaller than the amplitude C of the previously input signal is accurately detected.

However, if the slope at which the output signal Vout is reduced in FIG. 2B becomes too large, the maximum amplitude of the input signal Vin is not output but the input signal Vin is output as it is, I can not. Therefore, in order to realize an amplitude detecting apparatus that smoothly maintains the slope of the output signal Vout, the capacitance of the capacitor used as the charger 30 is sufficiently large or the current value of the added current source 40 This should be very small. However, a capacitor having a large capacitance is not suitable for implementation in an integrated circuit, and it is very difficult or impossible to control the current value of the current source 40 to a nano ampere level.

According to an aspect of the present invention, there is provided an amplitude detecting apparatus which can accurately detect an input signal having an amplitude smaller than a previously input signal by gradually lowering the potential of an output terminal, There is a purpose.

1 is a diagram showing an example of a conventional amplitude detecting device,

2 is a view showing another example of a conventional amplitude detecting device,

3 is a schematic circuit diagram and a simulation drawing of an amplitude detection apparatus according to the present invention.

DESCRIPTION OF REFERENCE NUMERALS

10: control means 20: switching means

30, 32: charger means 50: charger dispensing means

14: power supply unit 16: ground unit

(Configuration)

According to an aspect of the present invention for achieving the above object, there is provided an amplitude detection apparatus comprising: an amplitude detection unit for receiving an input signal having a predetermined amplitude from an external source and receiving a feedback signal having a predetermined level of voltage at another input, A control unit that receives a voltage of a predetermined level from the outside and receives a voltage of a predetermined level applied from the outside in response to a control signal applied from the control unit; A charging means for charging a voltage of a predetermined level outputted from the switching means; and a charging means connected between the switching means and the charger means for charging the charger means And a charger dispensing means for distributing the charred charge so that said switching means and said charge distribution An output terminal connected to each of the short and precisely detected regardless of the amplitude change of the input signal to the maximum amplitude of the input signal.

In a preferred embodiment of this aspect, the control means is an OP-Amp receiving an input signal having a predetermined amplitude from the outside with a non-inverting terminal and receiving a feedback signal having a voltage of a predetermined level with an inverting terminal.

In a preferred embodiment of this aspect, the switching means includes: an NPN bipolar transistor having a collector terminal connected to the power supply, a base terminal connected to the output terminal of the control means, and an emitter terminal connected to the other input terminal of the control means, to be.

In a preferred embodiment of this aspect, the charger means is a capacitor for charging a predetermined level voltage applied from the switching means, one end of which is connected to the output terminal of the switching means and the other end is connected to the grounding portion.

In a preferred embodiment of this aspect, the charger dispensing means has one end connected between the output terminal of the switching means and the charger means, and the voltage of a predetermined level outputted from the charger means is applied from the outside A first switching means having one end connected to the output terminal of the first switching means and the other end connected to the grounding portion and configured to charge a voltage of a predetermined level outputted from the charger means, And second switching means having one end connected between the output end of the first switching means and the capacitor and outputting the charge charged in the capacitor to the ground in response to a predetermined signal applied from the outside. Here, the first and second switching means alternately open and close in response to a predetermined signal applied from the outside.

(Action)

With this arrangement, the potential of the output terminal can be lowered at a constant rate, and therefore even when the amplitude of the input signal is smaller than the amplitude of the input signal previously input, the maximum amplitude of the input signal can be accurately detected.

(Example)

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

A charger distribution means 50 is added between the switching means 20 and the output terminal 12 so that the charger means 32 is connected to the output terminal 12, Charged charges are constantly supplied to the grounding unit 16 to lower the potential of the output terminal 12 at a constant rate. Therefore, the maximum amplitude of the input signal is accurately detected regardless of the amplitude change of the input signal Vin.

In Fig. 3, the same reference numerals are used for components having the same functions as the components of the amplitude detecting apparatus shown in Figs. 1 and 2.

Referring to FIG. 3A, an amplitude detecting apparatus according to the present invention receives an input signal Vin having a predetermined amplitude from the outside as one input terminal and inputs a feedback signal having a voltage (Vdd) (10) for receiving a voltage (Vdd) of a predetermined level from the outside and receiving a control signal from the control unit (10) (20) for outputting a voltage (Vdd) of a predetermined level applied from the outside to the other input terminal of the control means (10) in response to a signal of a predetermined level outputted from the switching means And a charger 32 connected between the switching means 20 and the charger means 32 for distributing charred charge to the charger means 32. Charge means 32 for charging the charging means Vdd, (50), and the Charge Index And an output terminal 12 for outputting a voltage value proportional to the charge amount charged in the stage 32. [

The control means 10 receives the input signal Vin having a predetermined amplitude from the outside with the non-inverting terminal and receives the feedback signal having the voltage Vdd of the predetermined level at the inverting terminal, Amp.

The switching means 20 has a collector terminal connected to the power source 14, a base terminal connected to the output terminal of the control means 10, and an emitter terminal connected to the other input terminal of the control means 10 Connected NPN type bipolar transistor.

The charging means 32 has one end connected to the output terminal of the switching means 20 and the other end connected to the grounding portion 16 so that the voltage Vdd ) Of the capacitor.

One end of the charger distribution means 50 is connected between the output terminal of the switching terminal 20 and the output terminal 12 to supply a predetermined level of voltage output from the charger means 32 to the outside A first switching means 52 having one end connected to the output terminal of the first switching means 52 and the other end connected to the grounding portion 16 so as to be connected to the charger means One end of which is connected between the output terminal of the first switching means 52 and the capacitor 54 and which is charged by the capacitor 54, And second switching means (56) for outputting the electric charge to the grounding unit (16) in response to a predetermined signal applied from the outside. Here, the first and second switching means 52 and 56 alternately open and close in response to a predetermined signal applied from the outside.

The operation of the amplitude detecting apparatus having the above-described configuration is as follows.

The control means 10 receives the input signal Vin and the feedback signal outputted from the switching means 20 and outputs a control signal of a high level when the input signal Vin is larger than the feedback signal, And outputs a low-level control signal to the switching means 20 when the input signal Vin is smaller than the feedback signal.

At this time, when the control signal is at a high level, the switching means 20 turns on and outputs a voltage Vdd of a predetermined level applied from the outside to the control means 10, The voltage Vdd of a predetermined level applied from the outside is not outputted.

The charger means 32 connected at one end to the output terminal of the switching means 20 is connected to the output terminal of the switching means 20 when the switching means 20 is turned on, And charges the charger to the charger means 32 through the charger distributing means 50 when the charger is turned off.

The charger dispensing means 50 for discharging the charger means 32 alternately performs an on-off operation of the first switching means 52 and the second switching means 56. Thus, the charge of the capacitor 54 of the charger distributing means 50 is charged or discharged so that the charred charge is caused to flow to the grounding unit 16 at a constant rate.

3B, so that even if the input signal Vin having an amplitude F smaller than the amplitude E of the previous input signal is input, The amplitude of the signal Vin is accurately detected.

According to the related art, when the input signal is smaller in amplitude than the previously input signal, the amplitude of the input signal can not be detected. Further, according to the improved prior art, although the amplitude of the input signal can be detected even when the amplitude of the input signal is smaller than that of the previous input signal, the capacity of the capacitor used is very large, and thus it is not suitable for an integrated circuit.

The present invention proposed in order to solve such problems of the prior art has a configuration in which charger distribution means is added between the output terminal of the switching means and the output terminal in the conventional amplitude detection device. Therefore, the charge charged in the charge means is flowed to the ground portion through the added charge distribution means at a constant rate, so that the amplitude of the input signal can be accurately detected regardless of the amplitude of the input signal, It is possible to implement an amplitude detection circuit that is easy to use in a circuit

Claims (6)

A feedback signal having a voltage Vdd of a predetermined level is input to another input terminal, and the two input signals are compared with each other, Control means (10) for outputting a control signal; (Vdd) of a predetermined level applied from the outside and in response to a control signal applied from the control means (10), a voltage (Vdd) A switching means (20) for outputting the output signal; A charger means (32) for charging a voltage (Vdd) of a predetermined level outputted from the switching means (20); And charger distribution means (50) connected between said switching means (20) and said charger means (32) for distributing the charred charge to said charger means (32) ) And the charger distribution means (50), the maximum amplitude of the input signal (Vin) is accurately detected regardless of the amplitude change of the input signal. The method according to claim 1, The control means 10 is an OP-Amp receiving an input signal Vin having a predetermined amplitude from the outside through a non-inverting terminal and receiving a feedback signal having a voltage (Vdd) at a predetermined level as an inverting terminal Wherein the amplitude detection device comprises: The method according to claim 1, The switching means (20) A collector terminal is connected to the power supply unit 14, a base terminal is connected to the output terminal of the control means 10, and an emitter terminal is connected to the other input terminal of the control means 10 Amplitude detection device. The method according to claim 1, The charger means (32) And a capacitor connected to the output terminal of the switching means 20 at one end and connected to the grounding portion 16 at the other end to charge a voltage Vdd of a predetermined level applied from the switching means 20 Amplitude detection device. The method according to claim 1, The charger dispensing means (50) And an output terminal of the switching means 20 is connected between the output terminal of the switching means 20 and the charger means 32 so that a voltage of a predetermined level outputted from the charger means 32 is outputted in response to a predetermined signal applied from the outside The first switching means 52, A capacitor 54 connected to the output terminal of the first switching means 52 and the other end connected to the grounding unit 16 for charging a voltage of a predetermined level outputted from the charger means 32, One end is connected between the output terminal of the first switching means 52 and the capacitor 54 to charge the charge charged in the capacitor 54 to the grounding unit 16 in response to a predetermined signal applied from the outside And a second switching means (56) for outputting the output signal. 6. The method of claim 5, Wherein the first and second switching means (52, 56) alternately open and close in response to a predetermined signal applied from the outside.