The subject invention relates to power supplies capable of providing multiple voltage outputs and low electromagnetic interference (EMI) noise for use in television receivers.

Typically, in television receivers, a PWM switched-mode power supply is used to supply these multiple output voltages. U.S. Patent 4,788,591 discloses such a PWM switched-mode power supply. However, since the voltage and current waveforms associated with such a supply are substantially square waves, a significant amount of EMI noise is generated in the television receivers. In fact, it has become common practice to install snubber (filter) circuits throughout the power supply circuit in the television receiver to reduce ringing and, consequently, to reduce the radiated EMI noise from the supply.

To reduce EMI noise generated from and eliminate snubber circuits used in switched-mode power supplies, resonant power supplies with soft-switching (i.e., zero- voltage-switching or zero-current switching) have been introduced. Fig. 1 shows the circuit schematic of a multi-resonant and multi-output dc-to-dc converter power supply proposed in the article "DESIGN OF HIGH-DENSITY ON-BOARD SINGLE- AND MULTIPLE- OUTPUT MULTI-RESONANT CONVERTERS", by T.A. Tabisz and F.C. Lee, HFPC, May, 1990 Proceedings, pp. 45-57. Due to resonant phenomenon, currents and voltages present in this converter possess the sine-wave like shape except for the gate-to-source voltage of the MOSFET Ql and the currents through the output rectifying diodes (D1-D6). Furthermore, all parasitics can be used in the converter design. Therefore, the amount of EMI noise generated in the converter is reduced and the snubber circuits are removed. However, the EMI noise generated in the driving circuit is still significant due to the square- wave voltage across the gate and source terminals of the MOSFET, and, consequently, a pulsating gate current with high di/dt is generated. To reduce the noise from the control circuit and the converter, the whole circuit is enclosed in a metal box for shielding, which is an expensive solution. It should be noted that the simple rectifying scheme used in the converter has potential switching losses and EMI noise problems when the converter is used

for high output voltage applications, such as for a TV power supply where one output voltage is 130 volts. These problems are caused by the recovery time of high voltage rectifying diodes.

An object of the present invention is to provide a power supply for a television receiver which has multiple output voltages and exhibits reduced radiated EMI.

It is a further object of the invention to provide such a power supply having a low switching loss, low EMI noise, and at least one high voltage (> lOOv.) output rectifying circuit.

Finally, it is another object of the present invention to provide such a power supply that is cost effective when compared to other prior art power supplies.

These objects are achieved in an improved multi-resonant and multi-output forward converter comprising an output transformer having a primary winding and at least two secondary windings each having a resonant capacitor and a series arrangement of two oppositely conducting diodes connected in parallel across the respective secondary winding for low output voltages (< 50V), and two oppositely conducting diode branches connected in parallel across the respective secondary winding for high output voltages (> 50V), each of said diode branches consisting of one high voltage fast recovery diode and one low voltage (100V reverse voltage) Schottky diode, a dc voltage source having a first terminal coupled to one end of said primary winding, a switching circuit coupled between the other end of said primary winding and a second terminal of said dc voltage source, and a switching signal source coupled to said switching circuit for controlling the ON/OFF cycling of said switching circuit through a gate filter, said switching circuit comprising transistor switching means having a switching terminal connected to the output terminal of said gate filter for receiving a switching signal from said switching signal source, a source terminal coupled to the second terminal of said dc voltage source and the ground terminal of said gate filter, and a drain terminal coupled to the other end of said primary winding, and a parallel arrangement of a flyback diode and a charging capacitor coupled across the source and drain terminals of said transistor switching means, said gate filter comprising two resistors and one capacitor having one of their two ends connected together, the other end of the first resistor being connected to the first terminal of said switching signal source, the other end of the second resistor being connected to the switching terminal of said transistor switching means, and the second end of said capacitor constitutes the ground terminal of said gate filter, the multi-resonance of the

forward converter including the resonant inductance and a combination of the capacitances of said output capacitors connected across the secondary windings and the capacitance of said charging capacitor.

Applicants have discovered that through the use of multi-resonance, the voltages and currents associated with the forward converter exhibit a sine-wave type shape, as opposed to a square-wave shape. As a result of this, there is less radiated EMI from the converter power stage. Furthermore, due to the reasons that the leakage inductance of the output transformer, junction capacitance of the switching transistor, and junction capacitances of the output rectifying diodes can be incorporated in the design of the resonant inductance and capacitances, the snubber circuits prevalent in a switch-mode TV power supply may be obviated.

In addition to the above, Applicants have proposed a new high voltage rectifying scheme by connecting one Schottky diode with 100V reverse voltage in series with a fast recovery high voltage rectifying diode. In doing so, problems, such as diode current spikes and extra switching loss, caused by the recovery time of high voltage rectifying diodes if the simple rectifying scheme shown in Fig. 1 is used for high output voltages, can be overcome.

Furthermore, Applicants have obtained from the analysis of the converter that by properly designing the values of the resonant inductance and the charging and output capacitors, it can be arranged that the voltage across the switching transistor reaches zero and stays at zero for a certain period of time before the switching transistor needs to turn on. As a follow-on to this, a second-order gate filter can be employed to increase the rise and fall times of both the gate voltage and current. Thus, the radiated EMI generated by the driving circuit can be substantially reduced without increasing switching loss in the switching transistor.

With the above and additional objects and advantages in mind as will hereinafter appear, the invention will be described with reference to the accompanying drawings, in which:

Fig. 1 shows a simplified circuit diagram of a prior art multi-resonant and multi-output forward dc-dc converter;

Fig. 2 shows a basic circuit diagram of the improved multi-resonant and multi-output TV power supply of the subject invention;

Fig.3a shows the equivalent circuit of the circuit of Fig. 2, while Figs. 3b-3e depict the four linear circuit modes of the switching states of a switching means Ql, and diodes Dl, D2 and D3;

Fig. 4 shows various waveforms in the equivalent circuit diagrams of Figs. 3a-3e;

Fig. 5a shows a prior art gate drive circuit, and Fig. 5b shows various voltage and current waveforms therein;

Fig. 6a shows the gate filter circuit of the present invention, and Fig. 6b shows the various voltage and current waveforms therein; Fig. 7a shows a simple output rectifying circuit used in the circuit of Fig.

1, while Fig. 7b shows various voltage and current waveforms therein;

Fig. 8a shows the high voltage rectifying circuit of the subject invention, while Fig. 8b shows the associated voltage and current waveforms therein; and

Fig. 9 shows a practical circuit diagram of the forward converter of the subject invention.

Fig. 2 shows a basic circuit diagram of the multi-resonant and multi- output forward converter of the subject invention. An output transformer 10 is shown having a primary winding 12 and a plurality of secondary windings 14.1-14.m. A source of dc voltage 16 is shown having its positive terminal connected through a resonant inductor 18 to one end of the primary winding 12. The negative terminal of the dc voltage source 16 is connected to the other end of the primary winding 12 through a switching circuit 20. The switching circuit 20 includes transistor switching means 22, by example in the form of a MOSFET having a drain electrode connected to the other end of the primary winding 12 and a source electrode connected to the negative terminal of the dc voltage source 16. A parallel arrangement of a flyback diode 27 and a charging capacitor 26 are connected across the source and drain electrodes of the MOSFET 22. A switching signal source 28 is connected to the base of the MOSFET 22 through a gate filter 30. The gate filter 30 includes a first resistor 32 having one end connected to the positive terminal of the switching signal source 28 and the other end connected to one end of a second resistor 34 and one end of a capacitor 36. The other end of the resistor 34 is connected to the base of the MOSFET 22. Finally, the other end of the capacitor 36 is connected to the negative terminal of the switching signal source and the dc voltage source, and to the source electrode of the MOSFET 22.

Each secondary winding 14. m includes an resonant capacitor 40. m and a series arrangement of a first and a second oppositely conducting rectifier diode 42. m and 44.m (or diode branches including diodes 42. m, 43. m and 44. m, 45. m for high voltage rectifying) connected in parallel across the respective secondary winding 14. m. A filter circuit, including the series arrangement of an output filter inductor 46. m and an output capacitor 48.m, is connected across the diode 44. m (or diode branch 44. m and 45. m) in each secondary circuit, a load 50. m being diagrammatically shown connected across each output capacitor 48.m.

In order to properly design the converter circuit, the following information has to be obtained in the steady state analysis:

* The total secondary resonant capacitance, i.e., C ₂ ⁼ f(n _t , n ₂ , ..., n,-,, and C ₂₁ , C ₂₂ , ..., C ₂ -J,

* Conditions for zero- voltage switching,

* Output regulation as functions of input voltage and output load, * Component stress.

To simplify the steady state analysis, the following conditions are assumed (with also reference to fig. 3).

* The transformer 10 has only one secondary minding 14. m and the turn ratio (n,) of the output transformer is 1: 1, hence the transformer is eliminated and the total secondary resonant capacitance C2 is equal to the resonant capacitor

40m, the first rectifier diode D2 is equal to 42m and the second rectifier diode D3 is equal to 44m..

* The transistor switching means Ql, the flyback diode Dl, and the first and second rectifier diodes D2 and D3 are ideal. The transistor switching means Ql is switched at a constant-off time to ensure the zero- voltage and zero-current turn-on.

* The inductance of the output filter inductor 46.m is large enough so that the output current I ₀ can be considered as constant.

* The converter circuit is loss-less. From the third assumption, the output circuit consisting of the output filter inductor 46.m, the output capacitor 48. m and the load 50.m can be replaced by a constant current source I ₀ . Thus, the equivalent circuit of the circuit shown in Fig. 2 can be obtained based on the above assumptions and is shown in Fig. 3a. This equivalent circuit possess four linear circuit modes depending on the switching states of The transistor switching means

Ql, the flyback diode Dl, the first rectifier diode D2 and the second rectifier diode D3, and the polarity of a first voltage V _cl accross the charging capacitor Cl (26) and a second voltage V- ₂ accross the total secondary resonant capacitance C2, as shown in Figs. 3b-3e. Table 1 shows the conditions for the occurrence of each circuit mode. In this table, it is assumed that to is the time when Ql is turned off, t,_ is the time when the second voltage v _c2 becomes negative, t ₂ is the time when the first voltage v _c ι reaches zero, and t ₃ is the time when the second voltage v _c2 becomes positive again.

TABLE 1

CONDITIONS FOR OCCURRENCE OF EACH CIRCUIT MODE

Circuit Ql Dl D2 D3 Conditions

Mode

Ml Off Off On Off Ql is turned off at to

M2 Off Off Off On v- ₂ = negative at t

M3 Off . On Off On v _cl = 0 at t ₂

Ql turned on/Dl conducts

M3 On Off Off On i„ > 0

M4 On Off On Off v "c.2, > 0 i _t > I ₀ at t ₃ M5 On Off On On ii _r ≤ Io at t ₃

The zero-voltage switching condition of this converter is accomplished by connecting the transistor switching means Ql, the flyback diode Dl, and the acharging capacitor Cl in parallel. Transistor switching means Ql is turned off at non-zero current. Due to the charge of charging capacitor Cl, the voltage across the transistor switching means Ql, i.e. the first voltage v _cl , will not be built up immediately, thus resulting in a capacitively snubbed tum-όff. Once the transistor switching means Ql is off, it should be turned on only

when the flyback diode Dl is conducting to achieve zero-voltage and zero-current turn on. Therefore, it is necessary to derive information such that the time interval during which the flyback diode Dl is conducting is known. Waveforms of typical currents and voltages over one switching period T _s and the time intervals associated with each circuit mode for the operation sequence M1-M2-M3-M4 are shown in Fig. 4.

A common practice to reduce the radiated EMI noise from the driving circuit is to add a resistor R in series between the IC driver and the gate of the MOSFET as shown in Fig. 5a, where waveforms of the gate current and voltage are depicted in Fig. 5b. Such a method is sufficient for passing EMI regulations, but the amount of EMI noise is still high enough to appear on a television screen due to the sharp di/dt of the gate current as seen in Fig. 5b. A large value of the resistor R can be used but this causes more power dissipation in the MOSFET. A new second-order RC gate filter is proposed in Fig. 6a where C _gs is the gate-to-source junction capacitance of the MOSFET. Due to the second- order resonance, the gate current possesses the damped sine-wave shape without increasing the power loss in the MOSFET, resulting in a significant noise reduction in the driving circuit. It should be noted that the current, shown in Fig. 6b, through a first resistor Rl still possesses the shape as shown in Fig. 5b. However, noise generated by this current can be easily reduced by placing the first resistor Rl and a capacitor C _gl close to the IC driver to minimize the current path. As shown in Fig. 7a, due to the recovery time of first and second high voltage (> 50V) rectifying diodes D21 (42.1) and D31 (44.1), a short circuit across the secondary winding of high output voltage (> 50V) may appear during the transition when the first and second high voltage rectifying diodes D21 and D31 exchange their conducting status, resulting in a large current spike. Such a current spike will not only cause extra power loss in the rectifying diodes, but also generate significant amounts of EMI noise. A novel rectifying circuit for high output voltages and low EMI noise is proposed in Fig. 8a, where the first and second 100V Schottky diodes D _s2 (43.1) and D^ (45.1) are added in series with the fast recovery first and second high voltage rectifying diodes D21 and D31. The operation principle is given as follows: assume that the first diode branch D _s2 /D21 is going to turn off and the second diode branch D^/TOl is going to turn on. When the voltage across the resonant capacitor C21 (40.1) V _c2 ι reaches zero and is going negative, Ds2m is off and D2m is in the recovery stage. When the voltage across the resonant capacitor C21 (40.1) V- ₂ ,-, becomes negative, the second Schottky diode D^ and the second high voltage diode D31 are on and the voltage across the resonant capacitor C21 (40.1) V _c2 ι is dropped on

the first Schottky diode D _s2 because the first high voltage rectifying diode D21 has not recovered yet. However, there is no short circuit due to the turn-off of the first Schottky diode D _j2 , therefore, no current spike appears. Since the voltage across the resonant capacitor C21 (40.1) V _c21 has a sinusoidal-like waveform, the voltage across the first Schottky diode D _s2 builds up slowly during the recovery period of the first high voltage D21. When rectifying diode D21 has recovered, the voltage across the resonant capacitor C21 (40.1) V _C2 i is mostly dropped on the first high voltage rectifying diode D21 due to its smaller junction capacitance when compared to that of the first Schottky diode D _s2 . Thus, the first Schottky diode D _s2 is never over stressed even though its maximum reverse voltage is only 100V. This is also true for the second Schottky diode D, ₃ .

Based on the following design specifications: Input Voltages - V^ = 115 V and V^ = 185 V; Output Voltage - V _0l = 130 V and V _o2 = 23 V; Load Currents - I _0l = 1.20 A and I _o2 = 1.30 A (full load) I,,, = 0.6 A and I _o2 = 0.65 A (half load)

Switching Freq. - 500 kHz. it has been determined that: the resonant inductor L _r = 37 μR the charging capacitor Cl = 1 nF the total secondary resonant capacitance C2 = 2.97 nF

While the design of the resonant circuit is complete, the converter has only one secondary side and the value of the total secondary resonant capacitance C2 is assumed at the primary side. These results must now be converted into a two- (or more) output case with secondary resonance. The turn ratio n ₂ for the 23 V output is given by the following equation:

V^M n, = = 3

' Λ where M, the converter voltage gain, is selected to be 0.565. Furthermore, the turn ratio n _t for the 130 V output is similarly given by the following equation:

V^M n, = = 0.5 V _0l

The values of the resonant capacitors C _2I and C _2m can be determined from the following

equation:

where P ₀ j is the output power at the first secondary, and P _o2 is the output power at the second secondary giving:

C ₂₁ = 655 pF and C^ = 3.15 nF.

Fig. 9 shows a practical embodiment of the multi-resonant and multi- output forward converter of the subject invention for off-line applications. In such applications, the dc voltage source 16 shown in Fig. 2 is obtained by rectifying a low frequency AC line voltage, for example, 50 Hz or 60 Hz, through an input circuit 16 consisting of an EMI filter, a full-wave rectifier, and an energy storage capacitor as shown in Fig. 9. In the input circuit 16, said EMI filter is employed to filter out the high frequency noise generated by the high frequency operation of the multi-resonant and multi-output forward converter. The ac line voltage is rectified by said full-wave rectifier to produce a pulsatory dc voltage which is smoothed by said energy storage capacitor 54. It should be noted that the capacitor 56, connected in parallel with the energy storage capacitor 54, is used for EMI noise filtering purposes. In addition, a further output capacitor 58.1/58.2 has been added in parallel to the output capacitor 48.1/48.2 in the filter circuit on each secondary winding 14.1/14.2, the output voltage being taken across capacitor 48.1/48.2. In addition to the above, it should be noted that the flyback diode (Dl) 24 has been eliminated and effectively replaced by the internal diode of the MOSFET (Ql) 22. The gate filter 30 also includes the series arrangement of two resistors 60 and 62 connecting the gate terminal of MOSFET 22 to ground and the series arrangement of two oppositely arranged zener diodes 64 and 66 also connecting the gate terminal to ground, the junction points between the resistors 60, 62 and the zener diodes 64, 66 being interconnected. And the switching signal source 28 is a feedback loup receiving the 130V output voltage and generating a switching signal connected to resistor 32. The values of each of the components are as follows:

Inductors:

18 (L _r ) - 33.0 μR

46.1 (L _0l ) - 760 μR

46.2 (L _o2 ) - 230 μR Capacitors:

26 (Cl) - 750 pF

36 470 pF

40.1 (C ₂₁ ) - 650 pF

40.2 (C ₂₂ ) - 3.15 nF

48.1 (C _0l ) - 10 μF

48.2 (C _o2 ) - 47 μF

54 330 μF

56 0.1 μF

58.1 0.1 μF

58.2 0.1 μF

Resistors:

32 120 ohms

34 56 ohm

60 1 kohms

62 1 kohms

Numerous alterations and modifications of the structure herein disclosed will present themselves to those skilled in the art. However, it is to be understood that the above described embodiment is for purposes of illustration only and not to be construed as a limitation of the invention. All such modifications which do not depart from the spirit of the invention are intended to be included within the scope of the appended claims.