JPH0282811A - Parabolic wave generating circuit - Google Patents

Abstract

PURPOSE:To always make the central time of a sawtooth wave coincident with the central time of a parabolic wave by detecting a peak of the sawtooth wave and using a voltage in response to the peak detection output for a reference voltage of an integration circuit. CONSTITUTION:A sawtooth wave G shown in figure C generated at a point G is applied to an inverting input terminal of an integration circuit 18 and a voltage shown in the figure C generated at a point F is applied to a noninverting input terminal of the circuit 18. Thus, a current flows to a capacitor 20 being a component of the integration circuit 18 in a direction as shown in figure at a period T1 in the figure C, the capacitor 20 is charged, while the capacitor 20 is discharged at a period T2. Since a switch 28 is closed in response to a vertical trigger pulse shown in figure A at a period T3 shown in the figure C, the integrating operation is stopped. The slope of the sawtooth wave G shown in the figure C is constant and a voltage at a noninverting input terminal (+) of a differential amplifier 19 is a half the amplitude of the sawtooth wave, the quantity of charging/discharging of the capacitor 20 is made equal to each other.

Description

DETAILED DESCRIPTION OF THE INVENTION (a) Field of Industrial Application The present invention is directed to the application of parabolic waves (
This relates to a quadratic curve waveform generation circuit.

(b) Prior Art A parabolic wave generation circuit capable of generating parabolic waves is described in Japanese Patent Application Laid-Open No. 125217/1983. FIG. 2 is a circuit diagram showing the parabolic wave generation circuit described in FIG. A capacitor (
3), an integrating circuit (4) that integrates the signal generated at the upper end A of the capacitor (3), and an output terminal (5).

A vertical drive pulse as shown in FIG. 3(a) is applied to the switch (1)
), the switch (1) opens and closes accordingly, and a sawtooth wave as shown in FIG. 3(b) is obtained at the upper end A.

Therefore, if the signal shown in FIG. 3(b) is integrated by the integrating circuit (4), a parabolic wave can be obtained at the output terminal (5).

By the way, as the integrating circuit in Fig. 2, a precision circuit using a differential amplifier circuit is generally used, and its reference voltage is
Average DC level of the signal in Figure (B) (a in Figure 3 (B))
is set to However, the center time 1 of the sawtooth wave in Fig. 3 (b). is later than the time t when the average DC level and the sawtooth wave intersect, so the capacitor built in the integration circuit is charged.

There was a problem in that the electric times did not match, and the time at the center of the sawtooth wave and the time at the center of the parabolic wave did not match. Therefore, the solution to such problems is
It is described in FIG. 3 of the above publication.

FIG. 5 is a circuit diagram showing the parabolic wave generation circuit described in FIG. 3 of the above-mentioned publication. A capacitor (3) that is charged according to a constant current from a constant current source (2), a coupling capacitor (4), an integrating circuit (base), an output terminal (6), and a second switch (7). Consisting of
The configuration is such that a parabolic wave is obtained at the output terminal (6). When a vertical trigger pulse as shown in FIG. 6(a) is applied to the first and second switches (1) and (7), r L in FIG. 6(a).

During the level period, the first switch (1) is opened and the second switch (7) is closed. Then, the capacitor (3) is charged, and the voltage at the upper end A of the capacitor (3) increases as shown in FIG. 6(b). Also, rH in Figure 6 (a)
During the level period, the first switch (1) is closed and the second switch (7) is opened, so that the capacitor (3) is discharged, and the voltage at its upper end A is as shown in Figure 6 (0). It rapidly descends. During the period when the second switch (7) is open,
The voltage at terminal (8) is at ground level, so
), a sawtooth wave as shown in FIG. 6(c) is generated. The signal in Figure 6 (C) is then integrated by the integrating circuit (5), but at this time, the signal waveform in Figure 6 (C) has an upper area and a lower area with the ground level as the boundary. Therefore, a parabolic wave with good symmetry as shown in FIG. 6(d) can be obtained at the output terminal (6).

(c) Problems to be Solved by the Invention However, the circuit shown in FIG. 5 requires a coupling capacitor (4) and cannot be constructed as a direct connection type, making it unsuitable for IC implementation. Furthermore, since the second switch (7) is inserted directly into the signal path, noise is generated during switching, which is a problem.

(d) Means for Solving the Problems The present invention has been made in view of the above points, and includes a sawtooth wave creation circuit that creates a sawtooth wave in response to a vertical trigger pulse, and a sawtooth wave creation circuit. It consists of a differential type integrating circuit that integrates the output sawtooth wave and generates a parabolic wave, and a peak detection circuit that peak-detects the output sawtooth wave of the sawtooth wave generation circuit, and the output of the peak detection circuit The invention is characterized in that the reference voltage of the integrating circuit is set according to the voltage.

(*〉According to the present invention, the sawtooth wave is peak-detected, and the voltage corresponding to the peak detection output is used as the reference voltage of the integrating circuit. Therefore, the center time of the sawtooth wave and the parabolic wave It is possible to always match the central time.

(v) Embodiment FIG. 1 is a circuit diagram showing an embodiment of the present invention, in which (6) shows a control transistor (8) to which a vertical trigger pulse from an input terminal (7) is applied to its base, and a constant A sawtooth wave generation circuit consisting of a charging/discharging capacitor (10) to which a constant current is supplied from a current source (9), (11> is a first level shift circuit that level-shifts the sawtooth wave generated at point B, ( 12
) further level-shifts the level-shifted sawtooth wave from the first level shift circuit (11). A second level shift circuit (13) is a transistor (23) and the first level shift circuit (6). (14) is a third level shift circuit for level shifting the sawtooth wave; (15) is a capacitor built in the third level shift circuit (14); (18) is a differential amplifier circuit (19), and an output terminal and a negative input terminal (-) of the differential amplifier circuit (19). This is an integrating circuit consisting of a capacitor (20) connected between the capacitor (20) and a resistor (21) whose one end is connected to the capacitor (20).

Next, the operation will be explained. Now, when a vertical trigger pulse as shown in FIG. A constant current from 9) flows to the charging/discharging capacitor (10), and the voltage at the upper end B of the charging/discharging capacitor (10) gradually increases. or,
rH of the vertical trigger pulse.

During the level period, the control transistor (8) is turned on, so
The charge/discharge capacitor (10) discharges rapidly. Therefore, a sawtooth wave as shown in Figure 4 (b) is obtained at point B, and the first
+4Vst (however, ■o
(forward voltage of the PN junction) is level-shifted. The level-shifted sawtooth wave is transferred to a second level shift circuit (
12) to the base of transistor (22) and to the base of transistor (23).

Since a peak detection capacitor (13) is connected to the emitter of the transistor (23), the applied sawtooth wave is peak detected and converted into a DC voltage.

Here, if the maximum amplitude of the sawtooth wave at point B is V, then the voltage vCo) at point C is V((+)-Vs+3V□...
. . . (1), and is expressed as the -dotted chain line C in FIG. 4(c).

Also, at the point which is the emitter of the transistor (22) -
A vBII level-shifted sawtooth wave is obtained, and the maximum value of the amplitude of the sawtooth wave V(o)maX is V(D)maX=
VB+ 3 VB! "...""..."...'(2), and the minimum value V(D)min is V(fl)min=3Vex...
・・・・・・・・・・・・(3) and Figure 4 (c)
It looks like a solid line.

The aforementioned voltage obtained at point C is -VB! at transistor (24). , after being level-shifted, is divided by a voltage dividing circuit (15).If the resistance values of the first and second resistors (16) and (17) constituting the voltage dividing circuit (15) are set equal, The voltage at point E is V CI+ ) ”%V, + 2 Vsi...
・・・・・・・・・・・・(4) and Figure 4 (c)
It looks like the solid line E. The voltage V C! ) is further level-shifted by the transistor (25), so the voltage V (F ) at point F becomes v(1)=■, +vBII...
...(5), as shown by the solid line F in FIG. 4(C).

On the other hand, the sawtooth wave obtained at the point is caused by the transistor (26)
and (27) -2V, l! Since the level is shifted, the maximum value V(o)max of the voltage V, , at point G is V(G)m
ay=Vs+Vat ”””・・・・・・・・・
...(6), and the minimum value v(G)''in is V (a) fnin = V st ...
・・・・・・・・・・・・(7) becomes Figure 4 (c)
It is shown as a dotted line G.

Here, as is clear from equations (5), (6), and (7), the solid line F in FIG. 4(c) becomes exactly the amplitude of the dotted line G.

The sawtooth wave G in FIG. 4 (C) generated at point G is applied to the negative input terminal (-) of the integrating circuit (18), and the voltage F in FIG. 4 (C) generated at point F is The voltage is incorrectly applied to the positive input terminal (+). Therefore, period T in Figure 4 (c).

The capacitor (2) that constitutes the integrating circuit (18) is
0) in the direction shown in the figure to charge the capacitor (20), and during period T, the capacitor (20)
is discharged. Furthermore, during the period T in FIG. 4(C), the switch (2) is activated in response to the vertical trigger pulse in FIG. 4(B).
8) closes, so the integral operation stops. The slope of the sawtooth wave G in FIG. 4(c) is constant, and the differential amplifier circuit (19)
Since the voltage at the positive input terminal (+) of the capacitor (20) is equal to the amplitude of the sawtooth wave, the amount of charging and discharging of the capacitor (20) can be made the same.

Therefore, the output terminal (29) of the integrating circuit (18) has a fourth
As shown in Figure (d), a parabolic wave whose apex coincides with the time t when the capacitor (20) switches from charging to discharging can be obtained.

(g) Effects of the Invention As described above, according to the present invention, the center times of the sawtooth wave and the parabolic wave can be made to coincide, so that a parabolic wave with good symmetry can be created.

[Brief explanation of the drawing]

Fig. 1 is a circuit diagram showing an embodiment of the present invention, Fig. 2 is a circuit diagram showing a conventional parabolic wave generation circuit, and Figs. 3 (a) and (b) are for explanation of Fig. 2. Waveform diagram of Fig. 4 (
A) to (D) are waveform diagrams for explaining FIG. 1, FIG. 5 is a circuit diagram showing a conventional parabolic wave generation circuit, and FIGS. FIG. 3 is a waveform diagram for explanation. (6)...Sawtooth wave creation circuit, (11)...Second
Level shift circuit, (12)...Second level shift circuit, (13)...Detection capacitor, (14)...
・Third level shift circuit, (18>...integrator circuit.

Claims (3)

[Claims] (1) a sawtooth wave creation circuit that creates a sawtooth wave in response to a vertical trigger pulse; a differential integration circuit that integrates the output sawtooth wave of the sawtooth wave creation circuit to generate a parabolic wave; a peak detection circuit that peak-detects the output sawtooth wave of the sawtooth wave generation circuit, and a parabolic wave generation characterized in that the reference voltage of the integration circuit is set according to the output voltage of the peak detection circuit. circuit. (2) The parabolic wave generation circuit according to claim 1, further comprising a voltage dividing circuit that divides the output voltage of the peak detection circuit into half and applies the divided voltage to the integrating circuit as a reference voltage. (3) a sawtooth wave creation circuit that creates a sawtooth wave in response to a vertical trigger pulse; a first level shift circuit that level shifts the output sawtooth wave of the sawtooth wave creation circuit; and the first level shift circuit. a second level shift circuit that level-shifts the output sawtooth wave of the first level shift circuit; a peak detection circuit that peak-detects the output sawtooth wave of the first level shift circuit; and divides and level-shifts the output voltage of the peak detection circuit. a third level shift circuit; and a differential type integration circuit that integrates the output sawtooth wave of the second level shift circuit based on the output voltage of the third level shift circuit, and an output terminal of the integration circuit. A parabolic wave generation circuit characterized by obtaining more parabolic waves.