JPS59176913A - D-class amplifier - Google Patents

Abstract

PURPOSE:To obtain the flat frequency characteristics of a D-class amplifier by adding a means which damps the resonance characteristics of an LPF to said LPF provided between a load and the output terminal of an output stage element and setting the resistance value of said damping means. CONSTITUTION:A driver circuit is connected to the gates of output stage elements 1 and 2 of a D-class amplifier respectively, and the pulse width modulating signal is delivered to the drain juncture with a switching operation. An LPF6 is connected to the juncture of elements 1 and 2 and a load 7. The LPF6 is provided with inductances L1-L3 connected in series to each other and capacitors C1-C3 and resistances Rd2 and Rd3 which are set between the junctures of inductances L1-L3 and an earth point. Then the resonance characteristics obtained by L1-L3 and C1-C3 of the LPF6 are damped by the Rd2 and Rd3. The values of these Rd2 and Rd3 are set to obtain the flat frequency characteristics of the D-class amplifier.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a class 0 amplifier, and particularly to an output stage thereof.
This relates to pass filters.

Conventionally, there was a device for making this glaze as shown in FIG.

In the figure, the positive power supply +B 1tllll output stage element FE
The source of T1 is connected to the positive power supply 4, and the gate is connected to the positive side drive circuit. The source of F"ET2 of the output stage element on the negative voltage side B side is connected to the negative power supply 5,
The gates of each positive (1+1
1. The drains of the negative output stage elements 1 and 2 are connected to one end of the inductance L of the low-pass filter 6, and the other end of the inductance L is grounded through the capacitor C and connected to the output terminal 3. .

A load 7 is connected between the output terminal 3 and ground.

Next, the operation will be explained.

In FIG. 1, the output stage elements 1.2 perform a switching operation by a drive circuit connected to each gate, and a pulse modulated signal (for example, a pulse width modulation signal)
is obtained. This pulse modulation signal is generated by the inductance L
The carrier component is removed by a low-pass filter 6 made up of a capacitor C and a capacitor C, and only the inframodulation signal can be obtained at the output terminal 3.

Since the conventional DH amplifier 10-pass filter is configured as described above, when the load 7 becomes infinite or close to it, the inductance of the low-pass filter 6 and the resonance frequency of the capacitance C are , the impedance when looking at the output side from the drain of the output stage element 1.2 is close to 0 f:! Therefore, when a pulse modulated by a signal close to this resonance frequency is output, the positive power supply 4 or the negative phase 1 source 5 follows the output stage element 1.2 and is grounded, and the output stage There were drawbacks such as elements 1 and 2 sometimes being destroyed. Further, at this time, there was also a problem in that an excessive current flowed through the inductance L and the capacitance CK.

Historically, when a 4th or 6th order low-pass filter was used,
In class ) amplifiers, it is necessary to reduce the average current of the carrier, so the value of the inductor directly connected to the output stage element must be set very high, which causes a peak in the output frequency characteristics.

This invention was completed in order to eliminate the drawbacks of the conventional ones as described above, and is a low-pass filter 6 for a class 0 amplifier.
By connecting a resistor within K, even if the load 7 becomes infinite, the impedance seen from the output side from the drain of the output stage element at the resonance point of the inductance L and capacitance C of the low-pass filter 6 does not become 0. The purpose is to provide a circuit that

The present invention will be explained below based on the drawings.

FIG. 2 is a circuit diagram showing an embodiment of the present invention. 1st
The difference from the diagram is that a dump resistor Rd is inserted at both ends of the inductance L of the low-pass filter 6.

Next, the operation of this invention will be explained.

Considering the case where the load 7 becomes infinite in FIG. 2, if the fixed point of the drain of the output stage element 1.2 contains a frequency component equal to the resonant frequency of the inductance L1 and the capacitance C of the low-pass filter 6, then At that frequency, when there is no resistor Rd, the impedance when looking at the output stage from the drain fixed point of output stage element 1.2 is O, but when resistor Rd is present, the impedance is 0 even at the 1ild wave number. No.

Therefore, unlike conventional low-pass filters, the fixed point of the drain of the output stage element 1.2 is not substantially grounded, and damage can be prevented. It can also prevent excessive current from flowing.

In the above embodiment, the low-pass filter of the class 0 amplifier uses a second-order LC filter, but in reality, a fourth-order, sixth-order, etc. filter may be used, and an example of such a case is shown below. What is shown is FIG.

That is, an inductor Li L2. is connected between the output terminal of the output stage element 1.2 and the load 7. A series circuit of Ls is connected,
Inductors L1 and Lt, i, t, and.

A capacitor CI is connected between the bonding point of and load 7 and ground.

C2+Cs are connected and unconnected, and a tamp resistor Rd2*Rds is connected in parallel with the inductors L and Ll.

Moreover, this inductor L,, L2. L., Conde.

Sensor C1s C2* Cs and resistance ■ζd,, Rd3
FIG. 4 shows the same wave number characteristics of the filter 6 composed of the following. (a) is when there is no dump resistor Rd, , Rd, and (b) is when there is no dump resistor Rd2. This is the characteristic when there is Rds.

In this characteristic, peaks occur at multiple locations because in class 0 amplifiers, in order to reduce the average carrier current in the output stage, the first stage inductor L1 must be increased to a certain extent. Inductor L
This occurs because et Ll becomes smaller than Ll.

Further, as shown in FIG. 5, inductors LI and Lt are connected in series between the output terminal of the output stage element 1゜2 and the load 7,
A capacitor C! is connected between the connection point of both inductors Ll and Lt and the ground! Also, inductor L! A capacitor C7 may be connected between the connection point of the load 7 and the ground, respectively, and a dump resistor 1 to d4 may be connected in series to the controller CI.

Furthermore, as shown in Fig. 6, the resistance 1 at low h', j wave numbers
To suppress the gravitational loss of td, a capacitor C4 is maintained in series with the 41 resistor 1ζd in the circuit of FIG. It may be a configuration.

In addition, although the case where FET was used as an output stage element was shown in the said cA Example, it goes without saying that a bipolar transistor may be used.

As described above, with this invention, tr! Since a dump resistor is connected to the low-pass filter of the class 9 amplifier, it is possible to prevent excessive current from flowing to the output stage elements at a specific frequency, and it is possible to prevent excessive current from flowing to the inductance and capacitance that make up the low-pass filter. can be prevented from flowing.

Further, by setting the tamp resistance to a predetermined value, it is possible to reduce variations in the frequency characteristics of the low-pass filter caused by changes in load.

[Brief explanation of the drawing]

Fig. 1 is a diagram showing the configuration of a conventional low-pass filter of a class 9 amplifier, Fig. 2 is a diagram showing a low-pass filter of a class 9 amplifier according to an embodiment of the present invention, and Fig. 3 is a diagram showing the configuration of a low-pass filter of a class 9 amplifier according to the present invention. This is the case where the low-pass filter is multistage, m
FIG. 4 is a diagram showing an example of the frequency characteristics of the low-pass filter in FIG. 3, and FIGS. 5 and 6 are diagrams showing other embodiments of the present invention. ■, 2... Output stage element (FET) 3...
...Output terminal 4...Positive power supply 5...Negative power supply 6
...Low pass filter 7 ...Loads Rd1 to Rd, ...Dump resistance patent applicant
Pioneer Corporation Figure 3 Figure 4

Claims (2)

[Claims] (1) Provided between the output end of the output stage element and the load,
A class 0 amplifier characterized in that a low-pass filter for removing carrier components is provided with means for damping resonance characteristics due to inductance and capacitance forming the low-pass filter. (2) A class 0 amplifier according to claim I81, wherein the tamping means is a resistor. (:() Claim 11J, characterized in that the dumping means is a series circuit of a resistor and a capacitor.>
'q', Class 0 amplifier described in item 1.