BRPI0901619A2 - bidirectional split power impedance bidirectional LED driver circuit - Google Patents

Abstract

BIDIRECTIONAL LIGHTING LED CIRCUIT IN BIDIRECTIONAL DIVIDED POWER IMPEDANCE. The present invention uses resistive, or inductive, or capacitive impedance connected in series to each other to divide the voltage of the bidirectional power source, thus using the divided power of the impedance component to drive the bidirectional driving LED in parallel connection. to the two impedance terminals.

Description

"Bidirectional LED Power Circuit and Two-way Split Power Impedance"

Invention History

(a) Field of the Invention

The bidirectional split power impedance two-way LED driver circuit is described in which an AC source or periodically alternating polarity power is used as the power source to provide resistive impedance components, or inductive impedance components, or capacitive impedance components. in mutual series connection where the power supply voltage is divided. Thus, it is characterized by the fact that the power divided by the two terminals of the first impedance and the second impedance is used to drive a bidirectional driving LED, or to drive at least two sets of bidirectional driving light emitting diodes which are respectively connected in parallel by the two. two terminals of the first impedance and the second impedance.

(b) Description of the Prior Art

Conventional LED drive circuit using AC or DC power supply is normally connected in series with current limiting resistors such as impedance to limit current to the LED, where the series connected resistive impedance voltage drop always results. in wasting power and heat accumulation that are the imperfections.

Summary of the Invention

The invention is characterized in that the first impedance consists of capacitive impedance components, inductive impedance components, or resistive impedance components and a second impedance consists of capacitive impedance components, inductive impedance components, or resistive impedance components; where the first impedance and the second impedance are in series connection to receive the following: (1) The AC source with a constant audible voltage and a constant or variable frequency; or

(2) The AC source of two-way sine wave voltage or two-way square wave voltage, or two-way pulse voltage voltage with constant or variable voltage and frequency or constant or variable period that is converted from a DC source; or

(3) The AC source of two-way sine wave voltage or two-way square wave voltage, or two-way pulse voltage voltage with constant or variable voltage and frequency or constant or variable period converted from the DC source which is further rectified from an AC source;

The divided power is formed at the first impedance and the second impedance by the input of the above mentioned powers, where the first LED and the second LED are connected in parallel inverse polarities to constitute a set of two-way LED driving light that is connected. in parallel by the two terminals of the second impedance and is driven by the power divided by the two terminals of the second impedance to emit light.

BRIEF DESCRIPTION OF DRAWINGS

Figure 1 is the schematic block diagram of bidirectional LED driver and bidirectional split power impedance.

Figure 2 is the exemplary circuit diagram of the invention.

Figure 3 is an exemplary circuit diagram of the invention illustrating that the bidirectional conduction LED set comprises a first LED and a diode in parallel connection of opposite polarities.

Figure 4 is an exemplary circuit diagram illustrating that the bidirectional conduction light emitting diode assembly is connected in a common current limiting resistor series. Figure 5 is an exemplary circuit schematic diagram illustrating that the two-way conduction light emitting diode assembly is Bidirectional conduction in the circuit of Figure 2 is additionally installed with a zener diode.

Figure 6 is an exemplary circuit diagram illustrating that the bidirectional driving light emitting diode assembly in the circuit of Figure 3 is additionally installed with a zener diode.

Figure 7 is an exemplary circuit diagram illustrating that the bidirectional driving light emitting diode assembly in the circuit of Figure 4 is additionally installed with a zener diode.

Figure 8 is an exemplary circuit diagram illustrating that the discharge / discharge device is connected in parallel by the two terminals of a light emitting diode and a series limiting current limiting resistor in the circuit of Figure 5.

Figure 9 is an exemplary circuit diagram illustrating that the discharge / discharge device is connected in parallel by the two terminals of a light emitting diode and a series limiting current limiting resistor in the circuit of Figure 6.

Figure 10 is an exemplary circuit diagram illustrating that the discharge / discharge device is connected in parallel by the two terminals of a light emitting diode and a series limiting current limiting resistor in the circuit of Figure 7.

Figure 11 is an exemplary schematic circuit diagram of the bidirectional LED driving assembly of the invention illustrating that the first light emitting diode is inversely parallel connected to a diode, and the second light emitting diode is connected in parallel to the diode. inverse with a diode, where the two appear in connection in series of opposite directions.

Figure 12 is an exemplary circuit schematic block diagram of the invention that is connected in series to the serial disconnect type bidirectional power input modulator.

Figure 13 is an exemplary circuit schematic block diagram of the invention that is connected parallel to the parallel connection type bidirectional power input modulator.

Figure 14 is a schematic circuit block diagram illustrating that the invention is serially connected with a serial disconnect-type bi-directional power modulator to receive the output power of the DC to AC inverter.

Figure 15 is an exemplary circuit schematic block diagram illustrating that the invention is connected in parallel with a bidirectional parallel-disconnect power modulator to receive the output power of the DC to AC inverter.

Figure 16 is an exemplary circuit schematic block diagram of the invention driven by the DC to AC inverter output power.

Figure 17 is an exemplary circuit schematic block diagram of the invention that is connected in series with impedance components.

Figure 18 is an exemplary circuit schematic block diagram of the invention illustrating that the impedance components in series connection perform serial connection, or parallel connection, or series and parallel connection by means of the switching device.

Figure 19 is an exemplary circuit diagram of the invention illustrating that the inductive impedance component of the second impedance is replaced by the self-coupled transformer voltage source side winding of the self-coupled transformer to thereby constitute a voltage rise.

Figure 20 is an exemplary circuit diagram of the invention illustrating that the inductive impedance component of the second impedance is replaced by the self-coupled transformer voltage source side winding of the self-coupled transformer to thereby constitute a voltage drop.

Figure 21 is an exemplary circuit diagram of the invention illustrating that the inductive impedance component of the second impedance is replaced by the primary side winding of the separation type transformer with separation type voltage change winding.

Figure 22 is an exemplary circuit diagram of the invention illustrating that the side winding of a self-coupled voltage change source and the self-coupled transformer is in parallel resonance with the parallel connected capacitive impedance component to constitute a voltage rise.

Figure 23 is an exemplary circuit diagram of the invention illustrating that the side winding of a self-coupled voltage change source and the self-coupled transformer is resonant in parallel with the capacitive impedance component connected in parallel to constitute a voltage drop.

Figure 24 is a schematic circuit diagram of the invention illustrating that the primary side winding of the separation type transformer with voltage change winding separation type is connected in parallel with a capacitive impedance component for a resonant state to appear in parallel.

DESCRIPTION OF MAIN COMPONENT SYMBOLS

C100, C102, C200: CapacitorCR100, CR101, CR102, CR201, CR202: DiodeSDI10, ESD102: Charge / Discharge Device

1100, 1103, 1104, 1200: Inductive Impedance Component

IT200: Separation Type TransformerL100: Bidirectional LED Driving Set

LED101: First LEDLED102: Second LEDR101, R102: Discharge Resistor

R100, R103, R104: Current Limiting Resistor ST200: Self-Coupled Transformer

UlOO: Bidirectional LED (LED) Circuit

WO: Self Coupled Voltage Shift Winding

Wl: Primary Side WindingW2: Secondary Side WindingZlOl: First Impedance

Z102: Second Impedance ZD101, ZD102: Zener Diode

300: Serial Connection Type Two-Way Power Modulator400: Parallel Connection Type Two-Way Power Modulator

500: Impedance Component600: Switching Device 4000: DC to AC Drive

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The bidirectional split power impedance two-way LED driver circuit is described "by the fact that at least one first impedance is comprised of capacitive impedance components, inductive impedance components, or at least a second impedance components." capacitive impedance, inductive impedance components, or resistive impedance components, at least one first light emitting diode and at least one second light emitting diode are in reverse polarity parallel connection so as to constitute at least one bidirectional conducting light emitting diode assembly which is connected in parallel by the two terminals of at least one second impedance, where the two terminals of at least one first impedance and at least one second impedance in mutual series connection are provided to receive the following: (1) The AC supply with a constant voltage listenable and a constant or variable frequency; or

(2) The AC source of two-way sine wave voltage or two-way square wave voltage, or two-way pulse voltage voltage with constant or variable voltage and frequency or constant or variable period that is converted from a DC source; or

(3) The AC source of two-way sine wave voltage or two-way square wave voltage, or two-way pulse voltage voltage with constant or variable voltage and frequency or constant or variable period converted from the DC source that is additionally rectified from an AC source;

The divided power is formed in the first impedance and the second impedance in series connection by the abovementioned powers to drive at least one set of two-way driving light-emitting diode, or to drive at least two sets of two-way driving light-emitting diodes which are respectively connected in parallel. by the two terminals of the first impedance and by the two terminals of the second impedance, to constitute the bidirectional light-emitting diode driver circuit in bidirectional divided power impedance.

Figure 1 is a schematic block diagram of bidirectional LED driver and bidirectional split power impedance, wherein the circuit function is operated by the LED directional driver circuit (U100) as shown in Figure 1, which comprises :

- The first impedance (Z10O) comprises:

(1) Consists of one or more of a type and one or more of one of the capacitive impedance components or inductive impedance components or resistive impedance components, or may be optionally installed as required by two or more of two types of impedance components, waved impedance component type has one or more than one component in series or parallel connection, or in series and parallel connection; or (2) At least one capacitive impedance component and at least one inductive impedance component are in mutual series connection, where their frequency is equal to the two-way power frequency from the power source such as the AC source, or the alternating polarity period. a constant or variable voltage and periodically constant or variable internal polarity source converted from the DC source so that a series resonance impedance state appears; or

(3) At least one capacitive impedance component and at least one inductive impedance component are in mutual parallel connection, where their frequency is equal to the power source bidirectional power frequency such as the AC source, or the alternating polarity period of a constant or variable voltage and periodically constant or variable alternating polarity source, converted from DC, so that resonance impedance state in parallel appears; or

- The second impedance (Z102) comprises:

(1) It consists of one or more of one type and one or more of one of the capacitive impedance components or inductive impedance components or resistive impedance components, or may be optionally installed as required by two or more of two types of impedance components, where Each type of impedance component has one or more components in series or parallel connection, or series and parallel connection; or

(2) At least one capacitive impedance component and at least one inductive impedance component are in mutual series connection, where their frequency is equal to the frequency of bidirectional power from the power source such as the AC source, or the alternating polarity period of one. constant or variable voltage and periodically constant or variable internal polarity source, converted from the DC source, so that a series resonance impedance state appears; or (3) At least one capacitive impedance component and at least one inductive impedance component are in mutual parallel connection, where their frequency is equal to the two-way power frequency from the power source such as the AC source, or the alternating polarity period. a constant or variable voltage and periodically constant or variable internal polarity source, converted from the DC source, so that parallel resonance impedance state appears;

- At least one first impedance (Z101) and at least one second impedance (Z102) are mutually connected, in which the two first impedance (Z101) and second impedance (Z102) terminals in series are provided for:

(1) The AC source with a constant audible voltage and a constant or variable frequency; or

(2) The AC source of two-way sine wave voltage or two-way square wave voltage, or two-way pulse voltage voltage with constant or variable voltage and frequency or constant or variable period that is converted from a DC source; or

(3) The AC source of two-way sine wave voltage or two-way square wave voltage, or two-way pulse voltage voltage with constant or variable voltage and frequency or constant or variable period converted from the DC source that is additionally rectified from an AC source;

A bidirectional LED (L100) LED array: It consists of at least one first LED (LED101) and at least one second LED (LED102) in parallel connection of reverse polarities, where the number of first LEDs (LED101) and the number of second LEDs (LED102) can be the same or different, and the first LED (LED101) and the second LED (LED102) are individually made up of one LED. direct current polarity light, or by two or more than two direct current polarity light-emitting diodes in series or parallel connection, or by three or more three direct current polarity light-emitting diodes, serially connected, in parallel or serial and parallel connection. One or more of a set of two-way driving light emitting diode (L100) may be optionally selected as required to be connected in parallel by both terminals of either or both of the first impedance (Z101) or the second impedance (Z102), wherein The divided power is formed by the two first impedance terminals (Z101) and the two second impedance terminals (Z102) by the power input, where the bidirectional conduction LED assembly (L100) which is connected in parallel by the two first impedance terminals (Z101) or the two second impedance terminals (Z102) is triggered by the divided power to emit light.

In the two-way LED (U100) driver circuit, the first impedance (Z101) and the second impedance (Z102) as well as the two-way LED (L100) assembly can be selected to be one or more of one as needed.

The divided power is formed at the first impedance and the second impedance in series connection by the above powers to drive at least one set of two-way driving light-emitting diode, or to drive at least two sets of two-way driving light-emitting diodes which are respectively connected in parallel. by the two terminals of the first impedance and by the two terminals of the second impedance, to constitute the bidirectional light-emitting diode driver circuit in bidirectional divided power impedance.

For convenience of description, the components listed in the circuit examples of the following exemplary embodiments are selected as follows:

(1) A first impedance (Z101) and a second impedance (Z102) as well as a bidirectional conducting LED array (L100) are installed in the embodied examples. However, the selected quantities are not limited in actual applications;

(2) The capacitive impedance of the capacitor is selected to represent the impedance components so as to constitute the first impedance (Z10O) and the second impedance (Z102) in the embodied examples, where capacitive, inductive and / or resistive impedance components can be selected. optionally as needed in actual applications where it is described in the following:

Figure 2 is an exemplary circuit schematic diagram of the invention consisting mainly of the following:

- a first impedance (Z10O): comprises at least one capacitive impedance component, especially the capacitor (C100), where the number of the first impedance may be one or more than one;

A second impedance (Z102) comprises at least one capacitive impedance component, especially the capacitor (C102), wherein the number of the second impedance may be more than one;

- At least one first impedance (Z101) and appeal at least a second impedance are in series connection, where the two terminals of their subsequent series connections are provided for:

(1) The AC source with a constant audible voltage and a constant or variable frequency; or

(2) The AC source of two-way sine wave voltage or two-way square wave voltage, or two-way pulse voltage voltage with constant or variable voltage and frequency or constant or variable period that is converted from a DC source; or

(3) The AC source of two-way sine wave voltage or two-way square wave voltage, or two-way pulse voltage voltage with constant or variable voltage and frequency or constant or variable period converted from the DC source that is additionally rectified from an AC source; In the aforementioned power input, the divided power is formed at the first impedance and the second impedance in series connection, where at least one bidirectional driving light emitting diode (LlOO) assembly is actuated by the divided power.

A set of bidirectional LEDs (L100): consists of at least one first LED (LED101) and at least one second LED (LED102) in parallel connection of reverse polarities, where the number of the first LED (LED101) and the number of the second LED (LED102) may be the same or different, in addition, the first LED (LED101) and the second LED (LED102) may consist of a direct current polarity light emitting diode; or two or more than two direct current polarity light-emitting diodes with serial or parallel connections; or three or more than three diodes of direct current polarity light in series or parallel connection or in series and parallel connection. The bidirectional conduction LED set (L100) can be optionally installed with one or more of a required assembly, where it is connected in parallel by both either the first impedance (Z101) or second impedance (Z102) terminals to form the divided power that is used to drive the bidirectional conduction LED set (L100) that is connected in parallel to the two first impedance (Z101) or second impedance (Z102) terminals to emit light, or

- At least one bidirectional conduction LED array (L100) is connected in parallel to the two terminals of at least one second impedance (Z102), that is, is connected in parallel by the two capacitor terminals (C102) which constitute the second impedance (Z102), so that it is equated by the power divided by the two capacitor terminals (C102), although the impedance of the first impedance (Z101) is used to limit its current, where in the case of capacitor (C100) (as a bipolar capacitor) being used as the first impedance component, the output current is limited by capacitive impedance;

The first impedance (Z101), the second impedance (Z102) and the two-way conduction LED assembly (L100) are connected according to the above-mentioned structure to constitute the two-way light-emitting diode (UlOO) driver circuit and via of the current distribution effect formed by the parallel connection of the bidirectional conduction LED set (LlOO) and the second impedance (Z102), the voltage variation rate across the two terminals of the bidirectional conduction LED set (L100), corresponding to the power supply voltage variation may be reduced;

The two-way split-impedance two-way LED driver circuit, with selections of the first LED (LED101) and the second LED (LED102) constituting the bidirectional two-way LED (L100) assembly in the bidirectional LED circuit breaker (U100), includes the following:

1. A first LED (LED101) which may consist of one LED, or more than one LED in direct polarity series connection, or in parallel connection of the same polarity or in serial connection and in parallel;

2. A second light emitting diode (LED102) may consist of one light emitting diode, or more than one light emitting diode in direct polarity series connection, or in parallel connection of the same polarity or in series and parallel;

3. The number of LEDs constituting the first LED (LED101) and the number of LEDs constituting the second LED may be the same or different;

4. If the number of LEDs constituting the first LED (LED101) or the second LED (LED102) respectively is one or more than one, the connection ratio of the respective LEDs may be the same or in different serial connection, parallel connection or serial and parallel connection;

5. The first LED (LED10) or the second LED (LED102) may be replaced by a diode (CR100), where the diode current direction (CR100) and operating current direction of the first diode LED (LED101) or the second LED (LED102) that is reserved for parallel connection are in parallel connection and reverse polarities.

As shown in Figure 3 which is an exemplary circuit diagram of the invention illustrating the bidirectional driving LED assembly is comprised of a first LED and a parallel reverse diode of reverse polarity.

The two-way LED driver circuit may be as shown in Figures 1, 2 and 3 when in actual applications, the following auxiliary circuit components may be optionally selected as required to be installed or not installed, although the amount of the installation may consist of a or more than one, where, if more than one is selected, they may be selected based on circuit function requirements to be serial or parallel or serial and parallel in corresponding polarities, where the components of Optionally selected auxiliary circuits include:

One diode (CR101): It is optionally installed as required to be connected in series with the first light emitting diode (LED101) to prevent reverse overvoltage;

- One diode (CR102): It is optionally installed as needed to be connected in series with the second light emitting diode (LED102) to avoid reverse overvoltage;

A discharge resistor (R101): Is an optionally installed component as required to be connected in parallel by the two capacitor terminals (C100) of the first impedance (Z101) to release the capacitor residual charge (C100); A discharge resistor (R102): Is an optionally installed component as required to be connected in parallel by the two terminals of the second impedance capacitor (C102) (Z102) to release the capacitor residual charge (C102);

- A current limiting resistor (R103): It is an optionally installed component as needed to be individually connected in series to each of the first light-emitting diode (LED10) of the bidirectional LED (L100) assembly, whereby usually the current passing through the first light emitting diode (LED101), wherein the current limiting resistor (R103) may also be replaced by an inductive impedance component (1103);

- A current limiting resistor (R104): It is an optionally installed component as needed to be individually connected in series to each of the second light-emitting diodes (LED102) of the bidirectional LED (L100) assembly, where it is used for limit current passing through the second LED (LED102); wherein the current limiting resistor (R104) may also be replaced by an inductive impedance component (1104);

- The current limiting resistors (R103) and (R104) can be installed respectively to the first light emitting diode (LED101) and the second light emitting diode (LED102) of the bidirectional conduction LED set (L100) simultaneously on the bidirectional light-emitting diode driver circuit (U100), either they can be replaced or can be installed in conjunction with a current limiting resistor (R100) to connect in series directly with the bidirectional driving light-emitting diode assembly (L100) to obtain the current limiting function, wherein the current limiting resistor (R100) can also be replaced by an inductive impedance component (1100). The bi-directional LED driver circuit (U100) is thus constituted by the circuit structure and selection of auxiliary circuit components as shown in Figure 4 which is an exemplary schematic diagram of the two illustrating that the bi-directional LED array is connected in series with a current limiting resistor;

In addition, to protect the LED and to prevent the LED from being damaged or have a reduced useful life due to abnormal voltage, a zener diode may be additionally connected in parallel by both the first LED (LED10) and second diode terminals. light emitting diode (LED102) in the two-way driving LED assembly (L100) of the two-way LED driving circuit (U100), as shown in the circuit examples of Figures 5 and 6, or the zener diode is first connected in series by At least one diode to produce a zener voltage function, the following is connected in parallel by the two terminals of the first light emitting diode (LED101) or the second light emitting diode (LED102);

As shown in Figure 5 which is an exemplary circuit diagram illustrating that the bidirectional conduction LED array in the circuit of Figure 2 is additionally installed with a zener diode.

Figure 6 is an exemplary circuit diagram illustrating that the bidirectional driving light emitting diode assembly in the circuit of Figure 3 is additionally installed with a zener diode;

Figure 7 is an exemplary circuit diagram illustrating that the bidirectional driving light emitting diode assembly in the circuit of Figure 4 is additionally installed with a zener diode; where it is constituted by the following:

1. A zener diode (ZD101) is connected in parallel by the two terminals of the first LED (LED10) of the two-way driving LED assembly (L100), where its polarity relationship is that of the zener diode (ZD101) is used to limit the operating voltage across the two terminals of the first light emitting diode (LED101);

The zener diode (ZD101) can optionally be connected in series with a diode (CR201) as required, where the advantages are: 1) the zener diode (ZD101) can be protected from reverse current; 2) both diode (CR201) and diodezener (ZD101) have temperature compensation effects.

2. If the second LED (LED102) is selected to constitute the bidirectional LED (L100) set, a zener diode (ZD102) may be selected to be connected in parallel by the two terminals of the second LED ( LED102), wherein the enter polarity ratio is both where the diode zener voltage (ZD102) is used to limit the operating voltage across the two terminals of the second LED (LED102);

The zener diode (ZD102) can be optionally connected in series with a diode (CR202) as required, where the advantages are: 1) the zener diode (ZD102) can be protected from reverse current; 2) both diode (CR202) and diode (ZD102) have temperature compensation effects.

The zener diode consists of the following:

(1) A zener diode (ZD101) is connected in parallel by the two terminals of the first LED (LED10) of the two-way driving LED assembly (L100), and a zener diode (ZD102) is connected in parallel by the two terminals. the second LED (LED102); or

(2) The two zener diodes (ZD101) and (ZD102) are connected in series inversely and are additionally connected in parallel by the two terminals of the two-way conduction light-emitting diode assembly (L100); or

(3) Can be replaced by parallel connection of a two-way zener diode in the two-way driving LED (L100) set circuit; All three circuits above can avoid high end overvoltage of the first LED (LED101) and the second LED (LED102);

The bi-directional LED driver circuit (U100) of the bi-directional split impedance two-way LED driver circuit as shown in the circuit examples of Figures 8,9 and 10, wherein to promote the lighting stability of the source LED light, the first LED (LED101) can be installed with a charge / discharge device (ESD101), or the second LED (LED102) can be installed with a charge / discharge device (ESD102). wherein the charge / discharge device (ESD101) and the charge / discharge device (ESD102) have the random charge and discharge characteristics that can stabilize the illumination stability of the first light emitting diode (LED10) and the second LED (LED102), I reduced your lighting pulses. The above discharge / discharge devices (ESD101) and (ESD102) may consist of conventional charge and discharge batteries, super capacitors or capacitors, etc .;

The two-way split-impedance two-way light-emitting diode driver circuit may be optionally additionally fitted with a discharge / discharge device as required, including:

1. The bidirectional split power impedance two-way LED driver circuit, whereas in its bidirectional LED driver circuit (U100), a charge / discharge device (ESD101) may be connected in parallel by the two resistor terminals current limiter (R103) and first light emitting diode (LED101) in series;

Or a charge / discharge device (ESD102) may additionally be connected in parallel by the two current limiting resistor (R104) and second light emitting diode (LED102) terminals in series connection;

Figure 8 is an exemplary circuit diagram illustrating that a discharge / discharge device is connected in parallel by the two terminals of the first LED, the second LED and the current limiting resistor in series connection on the circuit of Figure 5; which comprises:

- A charge / discharge device (ESD101) based on its polarity is connected in parallel by the two terminals of the first LED (LED10) and the current limiting resistor (R103) in series connection, or is directly connected in parallel by the two terminals. the first light emitting diode (LED10), wherein the discharge / discharge device (ESD10) has the random discharge / discharge characteristics to stabilize the lighting operation and reduce the illumination pulsation of the first light emitting diode (LED10);

- If the second LED (LED102) is selected for use, a charge / discharge device (ESD102) based on its polarity is connected in parallel by the two terminals of the second LED (LED102) and the current limiting resistor ( R104) in series connection, where the charge / discharge device (ESD102) has random charge / discharge characteristics to stabilize the lighting operation and reduce the illumination pulse of the second light emitting diode (LED102);

The above charge / discharge devices (ESD101) and (ESD102) may consist of conventional charge and discharge batteries, or super capacitors or capacitors, etc .;

2. The bidirectional split power impedance two-way LED driver circuit, if a first LED (LED101) is selected and is connected in parallel in reverse with a diode (CR100) on the LED driver bidirectional (U100), so its main circuit structure is as shown in Figure 9 which is an exemplary circuit schematic diagram illustrating that a charge / discharge device is connected in parallel by the two LED terminals and current limiting doristor in connection. Figure 6, in which a charge / discharge device (ESD101) based on its polarity is connected in parallel by the two terminals of the first LED (LED101) and the current limiting resistor (R103) in series, where the charge / discharge device (ESD101) has random charge / discharge characteristics to stabilize the operation. lighting and reducing the illumination pulse of the first light emitting diode (LED101);

The above charge / discharge devices (ESD101) and (ESD102) may consist of conventional charge and discharge batteries, or super capacitors or capacitors, etc .;

3. In the two-way LED (UlOO) driver circuit of the invention's two-way split-impedance two-way LED driver circuit, when the current limiting resistor (RlOO) is selected to replace the current limiting resistors (R103) and (R104) to serve as the common current limiting resistor of the bidirectional driving LED assembly (L100) on the LED driver circuit (U100), or the current limiting resistors (R103), (R104) and ( R100) are not installed, the main circuit structure is as shown in Figure 10 which is an exemplary schematic diagram illustrating that a charge / discharge device is connected in parallel by the two LED terminals and the current limiting resistor in series on the circuit of Figure 7, comprising:

- A charge / discharge device (ESD101) is directly connected in parallel by the two terminals of the first light emitting diode (LED101) of the same polarity and a charge / discharge device (ESD102) is directly connected in parallel by the two terminals of the second light emitting diode. (LED102) of the same polarity, where the charge / discharge devices (ESD101) and (ESD102) have random charge and discharge characteristics;

The above charge / discharge devices (ESD101) and (ESD102) may consist of conventional charge and discharge batteries, or super capacitors or capacitors, etc .;

4. If the charge / discharge devices (ESD101) or (ESD102) used are unipolar in items 1, 2 and 3 above, then the first LED (LED101) is connected in parallel with the unipolar charge / discharge device ( ESD101), a direct polarity serial connection diode (CR101) can be optionally installed as needed to prevent reverse voltage damage to the unipolar charging / discharging device, where after the second LED (LED102) is connected in parallel with the device Unipolar Charge / Discharge (ESD102), a direct polarity serial connection diode (CR102) can be optionally installed as required to prevent reverse voltage from damaging the unipolar charge / discharge device;

5. The two terminals of the bidirectional LED light assembly (L100) can optionally be connected in parallel with a bipolar charging / discharging device as required.

In addition, a charge / discharge device (ESD101) or a charge / discharge device (ESD102) can be additionally installed by the two terminals of the bidirectional LED light assembly (LlOO) on the bidirectional LED circuit breaker (U100). for random discharge / discharge, so that, in addition to stabilizing the lighting stability of the first LED (LED10) and the second LED (LED102) of the bidirectional LED (L100), charge device / discharge may provide its energy savings during a shutdown to trigger at least one of the first light emitting diode (LED101) or the second light emitting diode (LED102) to continue emitting light;

The above charge / discharge devices (ESD101) and (ESD102) may consist of conventional charge and discharge batteries, or super capacitors or capacitors, etc .;

The aforementioned two-way driving LED assembly (L100), in which the lighting functions of the two-way LEDs consist of the following:

(1) Consists of at least one first light-emitting diode (LED101) and at least one second light-emitting diode (LED102) in parallel polarity connection; (2) At least one first light-emitting diode (LED101) is connected in series in direct polarity with one diode (CR101), and at least one second light emitting diode (LED102) is connected in series with one diode (CR102), so the two are additionally connected in parallel inversely;

(3) A diode (CR101) is connected in parallel with at least one opposite LEDs (LED10) of opposite polarities and a diode (CR102) is connected in parallel with at least one second LED (LED102) in opposite polarities at that the two additionally connected in series inversely to constitute a bidirectional LED light assembly, as shown in Figure 11, which is an exemplary circuit schematic diagram of the invention bidirectional LED light assembly illustrating that the first LED The light is connected in parallel with one diode and the second light-emitting diode is connected in parallel with a diode in reverse polarities, where the two appear in series connection inversely.

(4) May consist of combinations of conventional circuits or components that enable the light-emitting diode to receive power and to emit light bi-directionally.

The first impedance (Z101), the second impedance (Z102) and the two-way conduction LED set (L100), as well as the first LED (LED10), the second LED (LED102), and various Optional auxiliary circuits mentioned above as shown in the circuit examples of Figures 1 to 11 are based on application needs, where they may be optionally installed or not installed as required, and the amount of installation includes one, where more than one is selected. , the corresponding polarity ratio shall be determined based on the requirement of the circuit function to perform serial connection, or parallel connection or serial and parallel connections; From this it is constituted as follows:

1. The first impedance (Z101) may consist of one capacitor (C100) or more than one capacitor (ClOO) in series or parallel connection or in series and parallel connection in multiple installations where each first impedance may be consisting of the same type of capacitive impedance components, inductive impedance components, or resistive impedance components, or other different types of impedance components, in which their impedance values may be the same or different;

2. The second impedance (Z102) may consist of one or more than one serial connection or parallel or serial and parallel connection in multiple installations, where each second impedance may consist of the same type of capacitive impedance components, inductive impedance components, or resistive impedance components, or other different types of impedance components, in which their impedance values may be the same or different;

3. The first light emitting diode (LED101) may consist of one or more of one in direct polarity serial connection, or in parallel connection of the same polarity, or in parallel and serial connection;

4. The second light emitting diode (LED102) may consist of one or more of one in direct polarity series connection, or in parallel connection of the same polarity, or in series and parallel connection;

5. In the two-way LED (UlOO) driver circuit:

(1) May be optionally installed with one bidirectional LED (LlOO) assembly or with more than one bidirectional LED (LlOO) assembly in series, parallel or series and parallel, wherein if one or more sets are selected to be installed, they may be triggered together by the split power of the same second impedance (Z102) or individually triggered by the split power that corresponds to each of the second multiple impedances (Z102) that are connected to each other. (2) If a charge / discharge device (ESD101) or (ESD102) is installed in the bidirectional light-emitting diode driver circuit (U100), then the LED (LED101) or (LED102) The two-way driving LED assembly (L100) is DC-powered to emit light continuously;

If the charge / discharge device (ESD101) or (ESD102) is not installed, then the current conduction for the light emitting diode (LED101) or (LED102) is intermittent, thus referring to the voltage voltage waveform. Full-cycle current-conduction input, direct-emitting light-emitting diode and direct-emitting light-emitting peak voltage of the LED in the bidirectional LED (LlOO) set can be selected corresponding to the LED ( LED10) or (LED102), where the selections include the following:

1) The peak voltage of direct voltage light emission is lower than the rated direct voltage of LED (LED10) or (LED102); or

2) The rated direct light emitting diode (LED10) or (LED102) is selected to be the peak emission of direct voltage light; or

3) If the current conduction for the light emitting diode (LED101) or (LED102) is intermittent, the direct light emission voltage peak may be selected correspondingly on the basis of the full current conduction cycle, provided that the principle is followed. The peak voltage direct emission of light does not damage the LED (LED10) or (LED102);

Based on the value and waveform of the aforesaid direct light-emitting voltage, the corresponding current value and the direct voltage versus direct resulting rate waveform are produced; however, the peak of direct light-emitting current will follow the principle of not damaging the light emitting diode (LED101) or (LED102);

The luminosity or modulation of stepped or lower-scale direct current versus relative light brightness can be controlled on the basis of the above value and direct current waveform;

6. The diode (CR100), (CR100), (CR102), (CR201) and (CR202) may consist of one diode, or more than one diode in direct polarity serial connection, or in parallel connection of the same polarity. , or serial and parallel connection, where devices can be optionally installed as required;

7. The discharge resistor (R101), (R102), and current limiting resistors (R100), (R103), (R104) may consist of one resistor, or more than one resistor in series or parallel connection or connection in series and parallel, where devices can be optionally installed as needed;

8. The inductive impedance components (1100), (1103), (1104) may consist of one impedance component, or more than one impedance component in series or parallel or series and parallel, in whereas the devices can be optionally installed as required;

9. The zener diodes (ZD101), (ZD102) may consist of one zener diode, or more than one zener diode in direct polarity serial connection, or in parallel connection of the same polarity, or in parallel and serial connection in parallel. that the devices can be installed optionally as required.

10. Charging / discharging devices (ESD101), (ESD102) may consist of one or more serial or parallel connections, or parallel and serial connections, where the devices may be optionally installed as required;

In the application of the bidirectional light emitting diode (U100) driver circuit, the following different types of bidirectional AC source may be provided for inputs, where bidirectional power includes:

(1) The AC source with a constant audible voltage and a constant or variable frequency; or (2) The AC source of two-way sine wave voltage, or two-way square wave voltage, or two-way pulse voltage voltage with constant or variable voltage and constant or variable frequency or period that is converted from a DC source; or

(3) The AC source of two-way sine wave voltage or two-way square wave voltage, or two-way pulse voltage voltage with constant or variable voltage and frequency or constant or variable period converted from the DC source that is additionally rectified from an AC source;

In addition, the following active demodulation circuit devices may optionally be further combined as required, where the applied circuits are as follows:

1. Figure 12 is an exemplary circuit schematic block diagram of the invention which is connected in series to the serial connection type bidirectional power modulator, wherein the serial connection type bidirectional power modulator comprises the following:

- A serial connection type bidirectional power modulator (300): Consists of conventional electromechanical components or solid-state power components and related electronic circuit components for modulating bidirectional power output.

The circuit operation functions are as follows:

(1) The serial connection type bidirectional power modulator (300) can be installed optionally as needed to be connected in series with the bidirectional LED circuit breaker (U100) to receive bidirectional power from the power source, where Bidirectional power is modulated by the serial connection type two-way power modulator (300) to perform power modulations such as pulse width modulation or current conduction phase angle control, or impedance modulation, etc., to drive the drive circuit. bidirectional light emitting diode (U100); or (2) The serial connection type bidirectional power modulator (300) may be optionally installed as required to be connected in series between the second impedance (Z102) and the two-way driving LED assembly (L100), where the Bi-directional split power across the two second-impedance terminals (Z102) is modulated by the serial connection type bi-directional power modulator (300) to perform power modulations such as pulse-width modulation or ensuing conduction phase angle control, or impedance, etc., to drive the bidirectional driving LED set (L100);

2. Figure 13 is an exemplary circuit schematic block diagram of the invention which is connected in parallel to a parallel connection type bidirectional power modulator, wherein the parallel connection type bidirectional power modulator is comprised of the following:

- A parallel connection type bidirectional power modulator (400): Consists of conventional electromechanical components or solid-state power components and related electronic circuit components for modulating bidirectional power output.

The circuit operation functions are as follows:

(1) The parallel connection type bidirectional power modulator (400) can be optionally installed as required, where its output terminals are connected in parallel with the bidirectional light-emitting diode driver circuit (U100), although its input terminals are provided to receive bidirectional power from the power source, where bidirectional power is modulated by the parallel-type bidirectional power modulator (400) to perform power modulations such as pulse width modulation or current conduction phase angle control, or impedance modulation, etc., to drive the bidirectional LED driver circuit (U100); or (2) The parallel connection type bidirectional power modulator (400) may be optionally installed as required, where its output terminals are connected parallel to the input terminals of the bidirectional LED (llOO) LED although input terminals are connected in parallel with the second impedance (Z102), whereby the two-way power divided by the two second impedance terminals (Z102) is modulated by the two-way parallel disconnect power modulator (400) to perform power modulations such as pulse width modulation or phase conduction phase angle control, or impedance modulation, etc., to drive the bidirectional conduction LED set (L100);

3. Figure 14 is an exemplary circuit schematic block diagram illustrating that the invention is serially connected with a bi-directional serial modulator power modulator to receive the output power of the DC to AC inverter, wherein the constitution of the DC inverter For AC, the serial connection type bidirectional power modulator includes the following:

- A DC to AC Inverter (4000): Consists of conventional electromechanical components or solid state power components and related electronic circuit components, where their input terminals are optionally provided as required to receive input from a constant or variable voltage DC source. , or a CCified source from an AC source, although its output terminals are optionally selected as necessary to provide a bidirectional two-way sine wave power, or bidirectional square wave or bidirectional pulse wave at a constant or variable voltage and constant or variable internal polarity frequency or period to be used as the power source to provide bidirectional power;

- A serial connection type bidirectional power modulator (300): Consists of conventional electromechanical components or solid-state power components and related electronic circuit components for modulating bidirectional power output;

Circuit operation functions are described as follows:

(1) The serial connection type bidirectional power modulator (300) can be optionally installed as required to the series-connected two-way LED driver circuit (Ü100). After the two are in series connection, they are connected in parallel with the DC to AC drive output terminals (4000), and the DC to AC inverter bidirectional power output (4000) is modulated by the connection type bidirectional power modulator. series (300) for performing power modulations such as pulse width modulation or current-conducting phase angle control, or impedance modulation, etc., to drive the bidirectional LED driver circuit (U100); or

(2) Serial connection type bidirectional power modulator (300) can be optionally installed as required to be serially connected between the second impedance (Z102) and the two-way driving LED assembly (L100), where the power Bi-directional split by the two terminals of the second impedance (Z102) is used to perform power modulations such as pulse width modulation or current conduction phase angle control, or impedance modulation, etc., to drive the light conduction LED assembly. bidirectional (L100);

Figure 15 is an exemplary circuit schematic block diagram illustrating that the invention is connected in parallel with a bidirectional parallel-type power modulator to receive the output power of the DC to AC inverter; wherein the constitution of the DC to AC inverter and the paired connection type bidirectional power modulation include the following:

- A DC to AC Inverter (4000): Consists of conventional electromechanical components or solid state power components and related electronic circuit components, where their input terminals are optionally provided as required to receive input from a constant or variable voltage DC source. , or a CCified source from an AC source, although its output terminals are optionally selected as required to provide bidirectional sine wave bidirectional power, or bidirectional square wave or bidirectional pulse wave at a constant or variable voltage and constant or variable alternate polarity periods or periods to be used as the power source to provide bidirectional power;

- A parallel connection type bidirectional power modulator (400): Consists of conventional electromechanical components or solid state power components and related electronic circuit components for modulating bidirectional power output;

Circuit operation functions are described below:

(1) A parallel connection type bidirectional power modulator (400) can be optionally installed as required, where its output terminals are connected parallel to the input terminals of the bidirectional light-emitting diode (U100) drive circuit and its terminals. Inputs are provided to receive the bidirectional power output of the DC to AC drive (4000), where the bidirectional power output of the DC to AC inverter (4000) is modulated by the parallel connection type bidirectional power modulator (400) to perform power modulations. power such as pulse width modulation or ensuing conduction phase angle control, or impedance modulation, etc., to drive the bidirectional LED driver circuit (U100); or

(2) Parallel connection type bidirectional power modulator (400) can be optionally installed as required, where its output terminals are connected in parallel with the input terminals of the bidirectional LED light assembly (L100), although its input terminals are connected in parallel with the second impedance (Z102), where the bidirectional divided power by the two terminals of the second impedance (Z102) is modulated by the parallel connection type bidirectional power modulator (400) to perform power modulations such as modulation. pulse width or ensuing conduction phase angle control, or impedance modulation, etc., to trigger the bidirectional conduction LED set (L100);

Figure 16 is an exemplary schematic circuit block diagram of the invention driven by a DC to AC inverter output power;

It mainly comprises:

- A DC to AC Inverter (4000): Consists of conventional electromechanical components or solid state power components and related electronic circuit components, where their input terminals are optionally provided as required to receive input from a constant or variable voltage DC source. , or a CCified source from an AC source, while its output terminals are optionally selected as needed to provide bidirectional sine wave bidirectional power, or bidirectional square wave or bidirectional pulse wave at a constant or variable voltage and frequency or periods of constant or variable internal polarity to be used as the power source to provide bidirectional power;

The circuit operation functions are as follows:

- The two-way LED (U100) driver circuit is connected in parallel by the output terminals of the conventional DC to AC inverter (4000); DC to AC drive input terminals (4000) are optionally provided as needed to receive input from a constant or variable voltage DC source, or a rectified DC source from an AC source;

The DC-to-AC drive output terminals (4000) can be optionally selected as required to provide bidirectional sine wave bidirectional power, or bidirectional square wave or pulsidirectional wave at a fixed or variable voltage and frequency or constant or variable polarity period such as the bidirectional power source for controlling and driving the bidirectional LED (UlOO) circuit breaker;

- In addition, the bidirectional light-emitting diode (U100) driver circuit can be controlled and can be driven by modulating the output power of the DC to AC inverter (4000), as well as by performing power output modulations such as such as pulse width modulation, or conductive current phase angle control, or impedance modulation, etc .;

6. The two-way LED driver circuit (U100) is arranged to be connected in series with at least one conventional impedance component (500) and additionally be connected in parallel with the power source, where the impedance (500) includes:

(1) An impedance component (500): comprises a component with resistive impedance characteristics; or

(2) An impedance component (500): comprises a component with inductive impedance characteristics; or

(3) An impedance component (500): comprises a component with capacitive impedance characteristics; or

(4) An impedance component (500): comprises a single impedance component with the combined impedance characteristics of at least two of resistive impedance, or inductive impedance, or capacitive impedance simultaneously to provide DC or AC impedances; or

(5) An impedance component (500): comprises a single impedance component with the combined impedance characteristics of inductive impedance and capacitive impedance, wherein its inherent resonant frequency is equal to the frequency or period of two-way power, so as to produce a state of resonance. parallel; or

(6) An impedance component (500): consists of one or more than one type of one or more of a capacitive impedance component, or inductive impedance component, or resistive impedance component, or two or more types of two types of impedance in series connection, or parallel connection, or series and parallel connection to provide DC or AC impedances; or

(7) An impedance component (500): consists of the mutual series connection of a capacitive impedance component and an inductive impedance component, where its inherent serial resonance frequency is equal to the frequency or two-way power source period of power to produce a series resonance state and final attention to the two terminals of the capacitive impedance component or the inductive impedance component appear in series resonance correspondingly;

Or the capacitive impedance and inductive impedance are in mutual parallel connection, where their inherent parallel resonant frequency is equal to the power source bidirectional power frequency or period, so as to produce a parallel resonant state and the corresponding final voltage appears.

Figure 17 is an exemplary circuit schematic block diagram of the invention that is serially connected with impedance components;

7. At least two impedance components (500) as in item 6 perform switching between serial connection, parallel connection and serial and parallel connection by means of a switching device (600) comprising electromechanical components or solid state components, for example. means for modulating the power transmitted to the bidirectional light-emitting diode (U100) driver circuit, wherein Figure 18 is an exemplary circuit schematic block diagram of the invention illustrating that the impedance components in serial connection perform serial connection, or connection. in parallel, or series connection and in parallel by means of the decoupling device.

The bi-directional split-impedance two-way LED driver circuit, in which the optionally installed inductive impedance component (1200) of the second impedance (Z102) can be additionally replaced by the power supply side winding of an inductive transformer, wherein The transformer may be a self-coupled transformer (ST200) with self-coupled voltage change winding or a transformer (IT200) with separation type winding;

Figure 19 is an exemplary circuit diagram of the invention illustrating that the inductive impedance component of the second impedance is replaced by the side winding of the self-coupled transformer voltage change source to constitute a voltage rise, as shown in Figure 19, the self-coupled transformer (ST200) has a self-coupled voltage change winding (WO) with voltage elevation function, ostermines b and c of the self-coupled voltage change winding (WO) of self coupled transformer (ST200) is the power provisioning side that replaces the inductive impedance component (1200) of the second impedance (Z102) to form the second impedance (Z102), wherein the output terminals a and c of the self-coupled voltage change winding (W0) ) The self-coupled transformer (ST200) is arranged to provide a source of rising voltage to drive the emitting diode assembly. bidirectional driving light (L100);

Figure 20 is an exemplary circuit diagram of the invention illustrating that the inductive impedance component of the second impedance is replaced by the self-coupled transformer voltage changeover side winding to constitute a voltage drop, as shown in Figure 20, the self-coupled transformer (ST200) has a self-coupled voltage change winding (WO) with voltage drop function, in which the terminals b and c of the self-coupled voltage change winding (WO) of the self coupled transformer ( ST200) is the power supply side that replaces the second impedance inductive component (1200) of the second impedance (Z102) to form the second impedance (Z102), wherein the aec terminals of the self-coupled voltage change winding (WO) The self-coupling transformer (ST200) are arranged to provide AC voltage drop to drive the LED light emitting diode. bidirectional solution (10000);

Figure 21 is an exemplary circuit diagram of the invention illustrating that the inductive impedance component of the second impedance is replaced by the primary side winding of the separation type with separation type voltage change winding, wherein as shown in Figure 21, the transformer The type of separation (IT200) comprises a primary lateral winding (W1) and a secondary lateral winding (W2) in which the primary lateral winding (W1) and the secondary lateral winding (W2) are separated, although the primary lateral winding (Wl) constitutes the second impedance. (Z102), wherein the secondary side winding (W2) output voltage of the split type transformer (IT200) can be optionally selected as required to provide AC voltage boost or voltage drop to drive the LED light assembly bidirectional (L100).

From the foregoing description, the inductive impedance component (1200) of the second impedance (Z102) is replaced by the transformer power supply side winding, wherein the secondary side of the separation type transformer (IT200) provides AC voltage rise or voltage drop source. to drive the bidirectional LED-driving assembly (L100).

The bidirectional split power impedance two-way LED driver circuit, in which the optionally installed inductive impedance component (1200) of the second impedance (Z102) can be additionally replaced by the power supply side winding of an inductive transformer to form the second impedance (Z102) that is connected in parallel with the capacitor (C200) to appear in parallel resonance, where the transformer may be a self-coupled transformer (ST200) with self-coupled voltage change winding or a transformer (IT200) with voltage shifting type separation. Figure 22 is an exemplary circuit diagram of the invention illustrating that the side winding of a self-coupled voltage change source of the self-coupled transformer is in parallel resonance with the parallel connected capacitor to constitute an elevation. detention in which co As shown in Figure 22, the self-coupled transformer (ST200) has a self-coupled voltage change winding (WO) with voltage elevation function, the terminals and the self-coupled voltage change winding (WO) have a transformer. self-coupled (ST200) correspond to the power supply side that replaces the second impedance inductive component (1200) of the second impedance (Z102) to be connected in parallel with the capacitor (C200), where its inherent parallel resonant frequency after connection in parallel equals the frequency of the bidirectional power source such as the AC source, or the period of alternating polarity constant or variable voltage and periodically constant or variable alternating polarity source converted from CC source to produce a parallel resonating state, so as to the second impedance (Z102) which is connected in series with the capacitor (C100) of the first impedance (Z101); optionally, the capacitor (C200) may optionally be connected in parallel with the aec inputs and b and b inputs of the self-coupled transformer (ST200), or other inputs selected as required, wherein the output terminals a and c of the self-coupling voltage change winding (W0) The self-coupled transformer (ST200) are arranged to provide AC voltage rise source for driving the bidirectional driving light emitting diode assembly (L100).

Figure 23 is an exemplary circuit diagram of the invention illustrating that the side winding of the self-coupled voltage change source of the self-coupled transformer is in parallel resonance with the parallel connected capacitor to constitute a drop in voltage, wherein, as shown In Figure 23, the self-coupled transformer (ST200) has a self-coupled voltage change winding (WO) with voltage drop function, wherein the terminals a and c of the self-coupled voltage change winding (WO) The self-coupled transformer (ST200) is the power supply side that replaces the inductive impedance component (1200) of the second impedance (Z102) to be connected in parallel with the capacitor (C200), where its resonant frequency in parallel after the Parallel connection is equal to the frequency of the two-way power from the power source such as the AC source, or the alternating polarity period of the voltage. are constant or variable and periodically constant alternating polarity source or DC source converted variable to produce a parallel resonance state to form the second impedance (Z102) which is connected in series with the first impedance capacitor (C100), additionally , the capacitor (C200) may optionally be connected in parallel with the inputs of the self-coupled transformer (ST200), or other inputs selected as required, where the self-coupled voltage change winding output terminals b and c (W0 ) The self-coupled transformer (ST200) is arranged to provide voltage drop AC source to drive the bidirectional light-emitting diode assembly (L100).

Figure 24 is an exemplary circuit diagram of the invention illustrating that the primary side winding of the separation type transformer with voltage change winding separation type is connected in parallel with a capacitor to appear in parallel resonance state; wherein as shown in Figure 24, the separation type transformer (IT200) comprises a primary side winding (W1) and a secondary side winding (W2), in which the primary side winding (W1) and secondary side winding (W2) are separated; the primary side winding (W1) is connected in parallel with the capacitor (C200), where its resonant frequency in parallel inherent after parallel connection is equal to the frequency of the two-way power source, such as the AC source or alternating polarity of constant or variable voltage and source of periodically constant or variable alternating polarityconverted from the DC source to produce a parallel resonant state to form the second impedance (Z102), which is connected in series with the first capacitor (ClOO) impedance (Z10O); In addition, the capacitor (C200) can optionally be connected in parallel with the inputs and b and inputs b and c of the self-coupled transformer (ST200), or other inputs selected as required, the secondary side winding (W2) voltage of the separation type is separated. (IT200) can be optionally selected as needed to have voltage rise or drop in voltage, and the secondary side winding AC source output is provided to drive the Bidirectional LED (LlOO) assembly.

From the foregoing description, the inductive impedance component (1200) of the second impedance (Z102) is replaced by the transformer power supply side winding and is connected in parallel with the capacitor (C200) for parallel resonance to appear as the second impedance, although the secondary side of the separation type transformer (IT200) provides AC voltage boost or voltage drop to drive the bidirectional conduction LED (LlOO) assembly.

The color of the individual LEDs (LED10), (LED102) of the two-way driving LED assembly (L100) in the two-way LED driving circuit (U100) of the power-impeding two-way LED driving circuit Bi-directional split can optionally be selected to consist of one or more than one color.

The location arrangement ratios between the individual LEDs of the bidirectional two-way driving LED (LlOO) assembly in the bidirectional two-way impedance two-way LED circuit breaker (U100) bidirectional includes the following: 1) sequential arranjolinear; 2) distributed sequentially in one plane; 3) cross-linear arrangement; 4) cross distribution in a plane; 5) arrangement based on specific geometrical measurements in a plane; 6) Position based 3D geometry measurement.

The two-way split-impedance two-way LED driver circuit, in which the modalities of its two-way light-emitting diode (UlOO) driver circuit comprise circuit components which include: 1) Comprises individual circuit components which are interconnected; 2) At least two circuit components combined with at least two partial operating units which are additionally interconnected; 3) All components are integrated together in a structure.

As summarized from the above descriptions, progressive power saving, low heat loss and low cost performance can be provided by the bidirectional light-emitting diode driver circuit divided by bidirectional charge / discharge by the uni-polar capacitor to drive the LED of light.

Claims (28)

1. Two-way split power impedance two-way LED driver circuit characterized by the fact that it uses the capacitive, or inductive, or resistive components to constitute at least a first impedance, and uses the capacitive, or inductive, or resistive components to constitute at least a second impedance, as well as use at least a first light emitting diode and at least a second light emitting reverse polarity parallel connection to form at least one bidirectional conduction light emitting diode assembly that is connected in parallel by the two terminals of at least a second impedance; the two terminals of at least one first impedance and at least one second impedance in mutual connection are provided to receive the following: the AC source with a constant or variable voltage and a constant or variable frequency; or the AC source of two-way sine wave voltage or two-way square wave voltage, or two-way pulse voltage voltage with constant or variable voltage and frequency or constant or variable period that is converted from a DC source; or the AC source of two-way sine wave voltage or two-way square wave voltage, or two-way pulse voltage voltage with constant or variable voltage and frequency or constant or variable period converted from the DC source that is additionally rectified from an AC source; A split circuit is formed on the first impedance and the second impedance in series connection by the above mentioned powers to drive at least one set of two-way driving light-emitting diodes, or to drive at least two sets of two-way driving light-emitting diodes which are respectively connected in parallel by the two terminals. of the first impedance and the two terminals of the second impedance to form the bidirectional light-emitting diode driver circuit in bidirectional split power impedance; which comprises: the first impedance (Z10O) comprises one or more of one types and one or more of one of the capacitive impedance components or inductive impedance components or resistive impedance components, or may be optionally installed as required by the two or more of two decomposing types. impedance, where each type of impedance components has one or more than one component in series or parallel connection, or in series and parallel connection; or at least one capacitive impedance component and at least one inductive impedance component are in mutual series connection, where their frequency is equal to the bidirectional power frequency from the power source such as the AC source, or the alternating polarity period of a constant voltage, or periodically constant alternating polarity variable and source or variable converted from CC source so that resonance impedance state appears in series; or at least one capacitive impedance component and at least one inductive impedance component are in mutual parallel connection, where their frequency is equal to the frequency of the bidirectional power source power such as the AC source, or the alternating polarity period of an audible constant voltage and periodically constant alternating polarity source or variable converted from DC source so that parallel resonance impedance state appears; wherein the second impedance (Z102) comprises one or more than one type and one or more of one of the capacitive impedance components or inductive impedance components or resistive impedance components, or may be optionally installed as required by the two or more of two types of impedance components. wherein each type of impedance components has one or more than one component in series or parallel connection, or series and parallel connection, or at least one capacitive impedance component and at least one inductive impedance component are in mutual series connection. where its frequency is equal to the frequency of the two-way power from the power source, such as the AC source, or the period of alternating polarity of a constant or variable voltage, and the periodically constant or variable alternating polarity source converted from the CC source of so that resonance impedance state ems appears series; or at least one capacitive impedance component and at least one inductive impedance component are in mutual parallel connection, where their frequency is equal to the bidirectional power frequency from the power source such as the AC source, or the alternating polarity period of a constant voltage or variable and periodically constant alternating polarity source or variable converted from the CC source so that a resonant impedance state appears in parallel, at least one first impedance (Z10O) and at least a second impedance (Z102) are connected to each other in series. Two terminals of first impedance (Z101) and second impedance (Z102) in series connection are provided for: the AC source with a constant or variable voltage and a constant or variable frequency; or the AC source of two-way sine wave voltage or two-way square wave voltage, or two-way pulse voltage voltage with constant or variable voltage and frequency or constant or variable period that is converted from a DC source; or the AC source of two-way sine wave voltage or two-way square wave voltage, or two-way pulse voltage voltage with constant or variable voltage and constant or variable period frequency converted from a DC source that is additionally rectified from an AC source; Two-way driving light emitting diode (L100) consists of at least one first light emitting diode (LED101) and at least one second light emitting diode (LED102) in parallel reverse polarity connection, where the number of first light-emitting diodes ( LED101) and the number of second LEDs (LED102) can be the same or different, and the first LED (LED101) and the second LED (LED102) are individually made up of a direct arising polarity LED , or by two or more than two light-current direct light polarity diodes in series or parallel connection, or by three or more than three direct current polarity light-emitting diodes in series, parallel connection or series and parallel connection; One or more than one sets of the two-way driving LED array (L100) may be optionally selected as required to be connected in parallel by both terminals of either or both of the first impedance (Z101) or the second impedance (Z102), wherein the The divided power is formed by the two first impedance terminals (Z101) and the two second impedance terminals (Z102) by the power input, where the bidirectional conduction LED set (L100) which is connected in parallel by the two terminals of the first impedance (Z101) or by the two terminals of the second impedance (Z102) is actuated by the divided power to emit light, wherein in the bidirectional light-emitting diode (U100) driver circuit, the first impedance (Z101) and the second impedance (Z102) as well as the set Two-way LED (L100) LEDs can be selected to be one or more than one as needed; m the divided power is formed at the first impedance and the second impedance in series connection by the abovementioned powers to drive at least one bidirectional driving light-emitting diode array, or to drive at least two sets of two-way driving light-emitting diodes which are connected respectively. in parallel by the two terminals of the first impedance and the two terminals of the second impedance, to constitute the bidirectional light-emitting diode driver circuit in bidirectional split power impedance. Bi-directional split-power impedance two-way LED driver circuit according to claim 1, characterized in that it consists primarily of the following: a first impedance (Z101) comprises at least one capacitive impedance component, especially the capacitor (C100). ), wherein the first impedance number may be or more than one, a second impedance (Z102) comprises at least one capacitive impedance component, especially the capacitor (C102), wherein the second impedance number may be or more than one; At least one first impedance (Z101) and appeal at least a second impedance are in series connection, where the two terminals of their subsequent series connections are provided for: AC source with a constant or variable voltage or a constant or variable frequency; or the AC source of two-way sine wave voltage or two-way square wave voltage, or two-way pulse voltage voltage with constant or variable voltage and frequency or constant or variable period that is converted from a DC source; or the AC source of two-way sine wave voltage or two-way square wave voltage, or two-way pulse voltage voltage with constant or variable voltage and frequency or constant or variable period converted to. from the DC source which is further rectified from an AC source, by the above power input, the divided power is formed at the first impedance and the second impedance in series connection, where at least one bidirectional LED (L100) LED is Powered by split power, a set of two-way driving LED (L100) consists of at least one first light-emitting diode (LED101) and at least one second light-emitting diode (LED102) in parallel reverse polarity connection, where the number of first LED (LED101) and number of second LED (LED102) can be the same or different, additionally, first LED (LED101) and second LED (LED102) can be individually by a direct current polarity LED; or two or more than two direct current polarity light-emitting diodes in series or parallel connections; or three or more than three direct current polarity light-emitting diodes in series or parallel connection or in series and parallel connection; The bidirectional driving light emitting diode assembly (L100) can be optionally installed with one or more of one assembly as required, where it is connected in parallel by both terminals of either or either of the first impedance (Z101) or the second impedance (Z102). ) to form the split power that is used to drive the two-way conduction LED assembly (L100) which is connected in parallel to the two first impedance (Z101) or second impedance (Z102) terminals to emit light; At least one bidirectional light-emitting diode assembly (L100) is connected in parallel to the two terminals of at least one second impedance (Z102), that is, connected in parallel by the two capacitor terminals (C102) which constitutes the second. impedance (Z102), so that it is equated by the power divided by the two capacitor terminals (C102) although the impedance of the first impedance (Z101) is used to limit its current, in which case the capacitor (C100), such as a capacitor bipolar, is used as the first impedance component, the output current is limited by capacitive impedance, where the first impedance (Z101), the second impedance (Z102) and the two-way conduction LED set (L100) are connected accordingly. with the above-described structure to form the bidirectional light-emitting diode (U100) driver circuit. Two-way split-impedance two-way LED driver circuit according to claim 1, characterized in that by the current distribution effect formed by the parallel connection of the two-way driving LED (LlOO) assembly and the second impedance (Z102), the voltage variation rate across the two terminals of the bidirectional driving light emitting diode assembly (L100) corresponding to the power source voltage variation may be reduced. Bi-directional split-impedance two-way LED driver circuit according to Claim 1, characterized in that the first LED (LED10) or the second light-emitting diode (LED102) can be replaced with a single diode. (CR100), where the diode operating current direction (CR100) and the operating current direction of the first light emitting diode (LED101) or second light emitting diode (LED102) that is reserved for parallel connection is in parallel inverse polarities. Bi-directional split-impedance two-way LED driver circuit according to claim 1, characterized in that the first LED (LED101) and the second light-emitting diode (LED102) constituting the set of bidirectional driving LEDs (L100) are installed simultaneously with current limiting resistors (R103) and (R104), the current limiting resistor (R100) can be connected directly in series with the bidirectional conducting LED set (L100) to replace or be installed in conjunction with current limiting resistors (R103) and (R104) to obtain current limiting function; or the current limiting resistor (R100) may also be replaced by an inductive impedance component (1100); The bidirectional light-emitting diode (U100) driver circuit is thus constituted by the circuit structure and selection of auxiliary circuit components. Bi-directional split-power impedance bi-directional LED driver circuit according to claim 1, characterized in that a zener diode can be additionally connected in parallel by the two terminals of the first LED (LED101) and the second LED (LED102) on the two-way driving light (LlOO) diode assembly of the two-way LED (U100) driver circuit, or the zener diode is first connected in series with at least one diode to produce a zener voltage function, It is then connected in parallel by the two terminals of the first LED (LED101) or the second LED (LED102); which consists of the following: a zener diode (ZD101) is connected in parallel by the two terminals of the first LED (LED101) to the bidirectional conduction LED set (L100), where its polarity relationship is such that zener diode zener diode (ZD101) is used to limit the operating voltage across the two terminals of the first LED (LED101); the zener diode (ZD101) can be optionally serially connected with a diode (CR201) as required, where The advantages are: zener diode (ZD101) can be protected from reverse current; and both diode (CR201) and zener diode (ZD101) have temperature compensation effects, if the second LED (LED102) is selected to be the bidirectional LED (L100) set, a zener diode (ZD102) can be selected to be connected in parallel by the two LED second terminals (LED102), where its polarity ratio is such that the zener diode zener voltage (ZD102) is used to limit the operating voltage by the Two terminals of the second LED (LED102); the zener diode (ZD102) can be optionally connected in series with a diode (CR202) as required, where the advantages are: zener diode (ZD102) can be protected from reverse current; and both diode (CR202) and zener diode (ZD102) have temperature compensation effects. Two-way split-impedance two-way light-emitting diode driver circuit according to claim 1, characterized in that the zener diode consists of the following: a zener diode (ZD101) is connected in parallel by the two terminals of the first diode light (LED10) of the bidirectional driving LED set (L100), and a zener diode (ZD102) is connected in parallel by the two terminals of the second LED (LED102); or the two zener diodes (ZD101) and (ZD102) are connected in series inversely and are additionally connected in parallel by the two terminals of the two-way conduction light-emitting diode assembly (L100); or may be replaced by a parallel connection of a bidirectional zener diode to the bidirectional driving light-emitting diode assembly circuit (L100); All of the above three circuits can avoid high end overvoltage of the first LED (LED101) and the second light emitting diode (LED102). Bi-directional split-impedance two-way LED driver circuit according to claim 1, characterized in that the first LED (LED101) can be installed with a charge / discharge device (ESD101) or The second light emitting diode (LED102) can be installed with a discharge / discharge device (ESD102), where the charge / discharge device (ESD101) and the charge / discharge device (ESD102) have random charge and discharge characteristics that can stabilize. the illumination stability of the first light emitting diode (LED10) and the second light emitting diode (LED102), so as to reduce its illumination pulses; The above charge / discharge devices (ESD101) and (ESD102) may consist of conventional charge and discharge batteries, or super capacitors or capacitors. Two-way split-impedance two-way LED driver circuit according to claim 1, characterized in that the application circuit with the additionally installed charging / discharging device includes: the two-way LED-driver circuit in bidirectional split power impedance, where in its bidirectional LED driver circuit (U100), a charge / discharge device (ESD101) may be connected in parallel by the two terminals of the current limiting resistor (R103) and the first LED light (LED101) in series connection, or a charge / discharge device (ESD102) may additionally be connected in parallel by the two current limiting resistor terminals (R104) and the second light emitting diode (LED102) in series connection, comprising : A charge / discharge device (ESD101) based on its polarity is connected in parallel by the two terminals. s of the first LED (LED10) and the current limiting resistor (R103) in series connection, or is directly connected in parallel by the two terminals of the first LED (LED101), where the discharge / discharge device (ESD101) features random discharge / discharge characteristics to stabilize the lighting operation and reduce the illumination pulsation of the first light emitting diode (LED101); if the second light emitting diode (LED102) is selected for use, a charge / discharge device (ESD102) based on its polarity is connected in parallel by the two terminals of the second LED (LED102) and the current limiting resistor (R104) in series connection, where the charge / discharge device (ESD102) has random charge / discharge characteristics for stabilize the lighting operation and reduce the illumination pulse of the second light emitting diode (LED102), where the charge / discharge devices The above-mentioned (ESD101) and (ESD102) can be constituted by conventional charging and discharging debates, or super capacitors or capacitors. Bi-directional split-power impedance bi-directional LED driver circuit according to Claim 1, characterized in that the application circuit with the unloaded charging / discharging device additionally includes: a first LED (LED10) is selected. and is connected in reverse with a diode (CR100) in the bidirectional LED driver circuit (U100), so its main circuit structure is such that a charge / discharge device (ESD101) based on its polarity is connected in parallel by the two terminals of the first light emitting diode (LED101) and the current limiting resistor (R103) in series connection, where the charge / discharge device (ESD101) has random charge / discharge characteristics to stabilize the lighting operation. and reduce the lighting pulsation of the first LED (LED101); charging / discharging devices (ESD101 ) and (ESD102) above may consist of conventional charge and discharge batteries, or super capacitors or capacitors. Bi-directional split-power impedance two-way LED driver circuit according to claim 1, characterized in that the application circuit with the unloaded charging / discharging device additionally includes: on the two-way LED driver circuit (U100 ), when the current limiting resistor (R100) is selected to replace the current limiting resistors (R103) and (R104) to serve as the common current limiting resistor of the two-way conduction LED assembly (L100) in the The light emitting diode (U100) or current limiting resistors (R103), (R104) and (R100) are not installed and comprise: A charge / discharge device (ESD101) is directly connected in parallel by the two terminals of the first emitter diode. (LED101) of the same polarity, and a charge / discharge device (ESD102) is directly connected in parallel by the two terminals. second LEDs (LED102) of the same polarity, where the discharge / discharge devices (ESD101) and (ESD102) have random discharge and discharge characteristics, where the charge / discharge devices (ESD101) and (ESD102) The aforesaid may consist of conventional discharge and discharge batteries, or super capacitors or capacitors. Bi-directional split-power impedance bi-directional LED driver circuit according to claim 1, characterized in that a charge / discharge device (ESD101) or a charge / discharge device (ESD102) can be additionally installed by the two terminals. of the two-way LED driving assembly (L100) on the two-way LED (UlOO) drive circuit for random charge / discharge, so as to stabilize the lighting stability of the first LED (LED101) and the second diode LED (LED102) of the two-way driving LED assembly (L100), the charging / discharging device can provide its energy saving during a shutdown to trigger at least one of the first LED (LED101) or the second LED (LED102) to continue emitting light, if the charging / discharging devices (ESD101) or (ESD102) used are After the first light emitting diode (LED101) is connected in parallel with the unipolar charging / discharging device (ESD101), a direct polarity series connecting diode (CR101) can be installed optionally as necessary to prevent reverse voltage from damaging the device. unipolar charging / discharging; where after the second light emitting diode (LED102) is connected in parallel with the unipolar charge / discharge device (ESD102), a direct polarity serial connection diode (CR102) can be optionally installed as needed to prevent reverse voltage from damaging the device The unipolar charge / discharge device, wherein the above charge / discharge devices (ESD101) and (ESD102) may consist of conventional charge and discharge batteries, or super capacitors or capacitors. Bi-directional split power impedance bi-directional LED driver circuit according to claim 1, characterized in that a diode (CR101) is connected in parallel with at least one first light-emitting diode (LED10) at opposite polarities; and a diode (CR102) is connected in parallel with at least one second light emitting diode (LED102) at opposite polarities, wherein the two are further serially connected in reverse to form a bidirectional conduction LED array. Two-way split-impedance two-way LED driver circuit according to claim 1, characterized in that the two-way LED (U100) driver board can be optionally installed with a light-emitting diode assembly. bi-directional drive (L100) or with more than one set of bi-directional LED (L100) in series connection, parallel connection or series and parallel connection, where one or more than one set is selected for installation, they can be triggered together by the split power of the same second impedance (Z102) or individually triggered by the split power that corresponds to each of the second multiple impedances (Z102) that are in series or parallel connection. A bidirectional split power impedance two-way LED driver circuit according to claim 1, characterized in that if the charging / discharging device (ESD101) or (ESD102) is not installed, then the current conduction to the LED (LED101) or (LED102) is flashing, where reference to the input voltage waveform and resulting full conduction cycle, the direct light emission current and the peak light emission voltage of each LED LEDs in the bidirectional conduction LED set (L100) can be correspondingly selected for the LED, if the current conduction for the LED light is intermittent, the direct emission peak voltage can be selected correspondingly with based on the current conduction cyclocomplete as long as the principle of direct light emission Do not damage the LED. Bi-directional split-power impedance two-way LED driver circuit according to claim 1, characterized in that if the charge / discharge device is not installed, then with the base value and waveform of the direct voltage of Subsequent light emission, the corresponding current value and direct voltage versus direct current waveform are produced; However the direct light emitting current will follow the principle of not damaging the LED (LED10) or (LED102). Bi-directional split-impedance two-way LED driver circuit according to claim 1, characterized in that it is connected in series to the series-type two-way bidirectional power modulator, wherein the two-way power type The serial connection consists of the following: A serial disconnect-type bidirectional power modulator (300) is comprised of conventional electromechanical components or solid-state power components and related electronic circuit components for modulating bidirectional power output; Circuit operation functions are as follows: The serial disconnect type bidirectional power modulator (300) can be optionally installed as required to be connected in series with the bidirectional light emitting diode driver circuit (U100) to receive the bi-directional power from the source of power, where the two-way power is modulated by the two-way serial connection type power modulator (300) to perform power modulations such as pulse width modulation or current-conducting phase angle control, or impedance modulation, to drive the drive circuit. bidirectional light-emitting diode (U100); or the series-disconnected bidirectional power modulator (300) can be optionally installed as required to be connected in series between the second impedance (Z102) and the two-way driving LED (LlOO) assembly, where the bidirectional divided power The two-second terminal impedance (Z102) is modulated by the serial connection type bidirectional power modulator (300) to perform power modulations such as pulse width modulation or consequent conduction phase angle control, or impedance modulation, to drive bidirectional driving light emitting diode assembly (L100). Bi-directional split-impedance two-way light-emitting diode driver circuit according to claim 1, characterized in that it is connected in parallel to a bi-directional power modulator of parallel connection type, wherein the bi-directional type power modulator of type The parallel-connected power modulator (400) consists of the conventional electromechanical components or solid-state power components and related electronic circuit components to modulate the bidirectional power output; Circuit operation is as follows: The Parallel Disconnect Bidirectional Power Modulator (400) can be optionally installed as required, where its output terminals are Parallel Connected with the Bidirectional Light-Emitting Diode Driver Circuit (U100), although its term Input signals are designed to receive the bidirectional power from the power source, where the bidirectional power is modulated by the parallel connection type bidirectional power modulator (400) to perform power modulations such as pulse width modulation or conduction phase angle control. current, or impedance modulation, to drive the bidirectional light-emitting diode (U100) driver circuit; or the bidirectional parallel-disconnect power modulator (400) can be optionally installed as required, where its output terminals are connected in parallel with the input terminals of the bidirectional LED light assembly (LlOO) although their input terminals are connected in parallel with the second impedance (Z102), whereby the two-way divided power by the two terminals of the second impedance (Z102) is modulated by the two-way parallel disconnect power modulator (400) to perform power modulations such as width modulation. pulse or current conduction phase angle control, or impedance modulation, to drive the bidirectional conduction LED set (L100). 19. Two-way split-impedance two-way LED driver circuit according to claim 1, characterized in that it is driven by the output power of the DC-to-AC inverter, which comprises: a DC-to-AC inverter (4000) is consisting of conventional electromechanical components or solid-state power components and related electronic circuit components, where their input terminals are optionally provided as required to receive input from a constant or variable voltage DC source, or a CC source from an AC source, although output terminals are optionally selected as needed to provide a bidirectional two-way sine wave power, or two-way square wave or two-way pulse wave at a constant or variable voltage and constant or variable internal polarity frequency or period to be used as the power source. power to provide bidirectional power, a serial disconnect-type bidirectional power modulator (300) is comprised of conventional electromechanical components or solid-state power components and related electronic circuit components for modulating bidirectional power output; The following circuitry is described: the series-disconnected bidirectional power modulator (300) can be optionally installed as required by the series-connected two-way LED (UlOO) driver circuit; After both are in series connection, they are connected in parallel with the DC-to-AC drive output terminals (4000), and the DC-to-AC drive (4000) bidirectional power output is modulated by the connection-type bidirectional power modulator. series (300) for performing power modulations such as pulse width modulation or current-conducting phase angle control, or impedance modulation, to drive the bidirectional LED driver circuit (U100); or the series-disconnected bidirectional power modulator (300) can be optionally installed as needed to be connected in series between the second impedance (Z102) and the two-way conduction LED set (L100), where the bidirectional split power The second two-impedance terminal (Z102) is used to perform power modulations such as pulse width modulation or current-conducting phase angle control, or impedance modulation, to drive the bidirectional conduction LED array (L100). A bidirectional split power impedance two-way LED driver circuit according to claim 1, characterized in that it is driven by the output power of the DC to AC inverter, which comprises: a DC to AC inverter (4000) is consisting of conventional electromechanical components or solid-state power components and related electronic circuit components, where their input terminals are optionally provided as required to receive input from a constant or variable voltage DC source, or a CC source from an AC source, although output terminals are optionally selected as needed to provide bidirectional two-way sine wave power, or two-way square wave or two-way pulse wave at a constant or variable voltage and frequency or periods of constant or variable internal polarity to be used as the power source. to provide bidirectional power; a parallel disconnect-type bidirectional power modulator (400) is comprised of conventional electromechanical components or solid-state power components and related electronic circuit components to modulate bidirectional power output; The circuit is described below: A parallel-disconnect bidirectional power modulator (400) can be optionally installed as required, where its output terminals are connected parallel to the input terminals of the bidirectional light-emitting diode (U100) and its input terminals are provided to receive bidirectional power output from the DC to AC inverter (4000), where the bidirectional power output of the DC to AC inverter (4000) is modulated by the parallel connection type bidirectional power modulator (400) to perform power modulations such co mo pulse width modulation or conduction phase angle control resulting from, or impedance modulation, to drive the bidirectional LED circuit breaker (U100); or the bidirectional parallel-disconnect power modulator (400) can be optionally installed as required, where its output terminals are connected parallel to the input terminals of the bidirectional LED light assembly (L100), although its input terminals are connected in parallel with the second impedance (Z102), where the bidirectional divided power by the two terminals of the second impedance (Z102) is modulated by the parallel connection type bidirectional power modulator (400) to perform power modulations such as pulse width modulation or driving phase angle control, or impedance modulation, to drive the bidirectional driving light emitting diode assembly (L100). A bi-directional split-impedance two-way light-emitting diode driver circuit according to claim 1, characterized in that it is driven by a DC-to-AC inverter output power, comprising mainly: a DC-to-AC inverter (4000 ) is comprised of conventional electromechanical components or solid-state power components and related electronic circuit components, where their input terminals are optionally provided as needed to receive input from a constant or variable voltage DC source, or a CCified source from an AC source. although its output terminals are optionally selected as necessary to provide bidirectional sine wave bidirectional sine wave power, or bidirectional square wave or bidirectional pulse wave at a constant or variable voltage and frequency or periods of constant or variable internal polarity to be used as the power supply to provide bi-directional power, where the circuit operating functions are as follows: the bi-directional LED driver circuit (U100) is connected in parallel by the output terminals of the conventional AC to DC inverter (4000); DC to AC drive input terminals (4000) are optionally provided as needed to receive input from a constant or variable voltage DC source, or a rectified DC source from an AC source, DC to AC drive output terminals (4000) can be optionally selected as needed to provide bidirectional sine wave bidirectional power, or bidirectional square wave or pulsed bidirectional wave at a fixed or variable voltage and constant or variable polarity period such as the bidirectional power source to control and drive the diode circuit breaker bidirectional light emitting diode (U100), in which additionally the bi-directional light emitting diode driver circuit (U100) can be controlled by modulating the output power of the DC to AC inverter (4000) as well as by performing power modulations for power output such as pulse width modulation, or conductive current phase angle control, or impedance modulation. Bi-directional split-impedance two-way LED driver circuit according to claim 1, characterized in that the bi-directional LED driver circuit (U100) is arranged to be connected in series with at least one impedance component. conventional (500) and additionally be connected in parallel with the power source, wherein the impedance (500) includes: an impedance component (500) comprises a component with resistive impedance characteristics; or an impedance component (500) comprises a component with inductive impedance characteristics; or an impedance component (500) comprises a component with capacitive impedance characteristics; or an impedance component (500) comprises a single impedance component having the combined impedance characteristics of at least two of resistive impedance, or inductive impedance, or capacitive impedance simultaneously to provide DC or AC impedances; or an impedance component (500) comprises a single impedance component having the combined impedance characteristics of inductive impedance and capacitive impedance, wherein its inherent resonant frequency is equal to the frequency or bidirectional power period, so as to produce a parallel resonant state; An impedance component (500) is comprised of one or more than one type of one or more of a capacitive impedance component, or inductive impedance component, or resistive impedance component or two or more types of impedance component types connected in series, or parallel connection, or series and parallel connection to provide DC or AC impedances; or an impedance component (500) is constituted by the mutual serial connection of a capacitive impedance component and an inductive impedance component, wherein its inherent serial resonance frequency is equal to the frequency or bidirectional power period of the power source to produce a resonant state. in series and the final voltage across the two terminal terminals of the capacitive impedance component or inductive impedance component resonates in series correspondingly; or capacitive impedance and inductive impedance are in mutual parallel connection, where their inherent parallel resonance frequency is equal to the frequency or period of the bidirectional power source power, so as to produce a parallel resonant state and the corresponding final voltage appears. Bi-directional split power impedance two-way LED driver circuit according to claim 1, characterized in that the optionally installed inductive impedance component (1200) of the second impedance (Z102) can be additionally replaced by the supply side winding with an inductive effect transformer, wherein the self-coupled transformer (ST200) has a self-coupled voltage change winding (WO) with a voltage lift function, the terminals b and a self-coupled voltage change winding (WO) The self-coupling transformer (ST200) is the power supply side that replaces the inductive impedance component (1200) of the second impedance (Z102) to form the second impedance (Z102), wherein the output terminals a and c Self-coupled voltage change winding (WO) and self-coupled transformer (ST200) are arranged to provide AC voltage rise to drive the bidirectional driving light emitting diode assembly (L100). Bi-directional split power impedance bi-directional LED driver circuit according to claim 1, characterized in that the optionally installed inductive impedance component (1200) of the second impedance (Z102) can be additionally replaced by the supply side winding of power of an inductive transformer, wherein the self-coupled transformer (ST200) has a self-coupled voltage change winding (WO) with voltage drop function, in which the terminalsb and c of the auto voltage change winding coupled (WO) self-coupled transformer (ST200) is the power supply side that replaces the inductive impedance component (1200) of the second impedance (Z102) to form the second impedance (Z102), wherein the terminals a and c self-coupled voltage-shifting (WO) windings of the self-coupled transformer (ST200) are arranged to the detent to drive the two-way driving LED assembly (L100). Bi-directional split power impedance bi-directional LED driver circuit according to claim 1, characterized in that the optionally installed inductive impedance component (1200) of the second impedance (Z102) can be additionally replaced by the supply side winding of power of an inductive transformer, wherein the split type transformer (IT200) comprises a primary side winding (W1) and a secondary side winding (W2) in which the primary side winding (W1) and the secondary side winding (W2) are separate, although the primary side winding (W1) constitutes the second impedance (Z102), wherein the secondary side winding (W2) output voltage of the separation type transformer (IT200) can be optionally selected as needed to provide AC voltage boosting or voltage drop to drive emitting diode assembly bidirectional driving light (L100), wherein the inductive impedance component (1200) of the second impedance (Z102) is replaced by the transformer power supply side winding, where the secondary type transformer type side (IT200) provides AC source for voltage rise or voltage drop to drive the bidirectional driving LED assembly (L100). Bi-directional split power impedance two-way LED driver circuit according to claim 1, characterized in that the optionally installed inductive impedance component (1200) of the second impedance (Z102) can be additionally replaced by the supply side winding with an inductive effect transformer, wherein the self-coupled transformer (ST200) has a self-coupled voltage change winding (WO) with a voltage lift function, the terminals b and a self-coupled voltage change winding (WO) self-coupled transformer (ST200) correspond to the power supply side that replaces the second impedance inductive component (1200) to be connected in parallel with the capacitor (C200), where its inherent parallel resonant frequency after parallel connection is equal to the frequency of the bidirectional power of p such as the AC source, or the period of alternating polarity constant or variable voltage and periodically constant or variable alternating polarity source converted from CC source to produce a parallel resonance state, so as to form the second impedance (Z102) that is connected at series with the first impedance capacitor (C100) (Z101), additionally the capacitor (C200) can be optionally connected in parallel with inputs a and c and inputs b and a self-coupled transformer (ST200), or other inputs as required, where the terminals and ec outputs of the self-coupled voltage change winding (WO) and self-coupled transformer (ST200) are arranged to provide AC voltage rise source for driving the bidirectional LED light assembly (L100). A bidirectional split power impedance two-way LED driver circuit according to claim 1, characterized in that the optionally installed inductive impedance component (1200) of the second impedance (Z102) can be additionally replaced by the supply side winding of power of an inductive transformer, wherein the self-coupled transformer (ST200) has a self-coupled voltage change winding (WO) with voltage drop function, wherein the terminals a and c of the voltage change winding Self-coupled (WO) self-coupled transformer (ST200) is the power supply side that replaces the second impedance inductive impedance component (1200) to be connected in parallel with the capacitor (C200), where its frequency parallelin resonance after parallel connection equals the frequency of bidirectional power from the power source. such as the AC source, or the period of alternating constant or variable voltage polarity and periodically constant alternating polarity source or DC source converted variable to produce a parallel resonance state, to form the second impedance (Z102) which is serially connected with the first impedance capacitor (ClOO) (Z101), additionally, the capacitor (C200) can optionally be connected in parallel with the inputs with the self-coupled transformer (ST200), or other inputs selected as required, where the output terminals b and c of the self-coupling voltage change winding (WO) and self-coupling transformer (ST200) are arranged to provide AC voltage drop source for driving the bidirectional LED light assembly (L100). Bi-directional split power impedance bi-directional LED driver circuit according to claim 1, characterized in that the optionally installed inductive impedance component (1200) of the second impedance (Z102) can be additionally replaced by the supply side winding of power of an inductive transformer, wherein the separation type transformer (IT200) comprises a primary side winding (W1) and a secondary side winding (W2), in which the primary side winding (Wl) and the secondary side winding (W2) is separate; the primary side winding (W1) is connected in parallel with capacitor (C200), where its inherent parallel resonance frequency after parallel connection is equal to the frequency of power source bidirectional power such as the AC source, or the. constant polarity period of constant or variable voltage and periodically constant polarity source or variable source converted from the DC source to produce a parallel resonance state, thus constituting the second impedance (Z102), which is connected in series with the capacitor (ClOO) of the In addition, the capacitor (C200) can optionally be connected in parallel with the aec or b inputs and autocoupled transformer inputs (ST200), or other inputs selected as required, the secondary side winding output voltage (W2) of the Separation type transformer (IT200) can be optionally selected as required to have voltage rise or voltage drop-, and the AC side output of the secondary side winding is provided to drive the bidirectional conduction LED set (L100); wherein the inductive impedance component (1200) of the second impedance (Z102) is replaced by the transformer power supply side winding and is connected in parallel with the capacitor (C200) for parallel resonance to appear to constitute the second impedance, although the secondary side of the separation type transformer (IT200) provides AC elevation source. voltage or voltage drop to drive the bidirectional driving LED set (L100).