This application claims the benefit of Korean Patent Application No. 10-2005-117245, filed on Dec. 2, 2005, in the Korean Intellectual Property Office, the disclosure of which is incorporated herein in its entirety by reference.
1. Field of Invention
The present invention relates to a ballast integrated circuit (IC), and more particularly to a ballast IC for automatically adjusting a dead time according to load characteristics.
2. Description of Related Art
The inverter circuit for driving the fluorescent lamp 100 includes first and second switching elements 121 and 122 operated by ballast IC 110. The first switching element 121 and the second switching element 122 can be N-channel MOS transistors. Gate terminals of the first and second switching elements 121 and 122 are connected to the ballast IC 110. A DC voltage VDC is applied to a drain terminal of the first switching element 121, and a source terminal of the first switching element 121 is connected to the drain terminal of the second switching element 122 and the output node (a). The drain terminal of the second switching element 122 is coupled to the source terminal of the first switching element 121 and the output node (a), and the source terminal of the second switching element 122 is grounded.
A first resonance capacitor CS for resonance is coupled between the output node (a) and the fluorescent lamp 100, and a second resonance capacitor CP is coupled in parallel to the fluorescent lamp 100. An inductor L for limiting a current signal is coupled between the output node (a) and the first resonance capacitor CS, and an equivalent capacitor CCP for use in a charge pump is connected in parallel to the inductor L.
The above-mentioned driving circuit drives the first and second switching elements 121 and 122, generates an AC output voltage VO in the form of a square wave signal via the output node (a), and drives the fluorescent lamp 100. In this implementation the ballast IC 110 compensates for negative impedance characteristics of the fluorescent lamp 100, such that it ballasts (or stabilizes) the current signal when driving the first and second switching elements 121 and 122. The fluorescent lamp may be considered to be a single load resistor RL. In this case, the load resistor RL is connected in parallel to the second resonance capacitor CP.
Therefore, the characteristics of the resonance circuit composed of first and second resonance capacitors CS and CP and the load resistor RL vary according to the magnitude of the load resistor RL. The ballast IC is operated in three different modes according to the different resonance-circuit characteristics.
Referring to
According to the above-mentioned resonance characteristics, the ballast IC drives the fluorescent lamp 100 using three modes: a preheating mode, an ignition mode, and a running mode. The fluorescent lamp 100 is sequentially driven in the order of the preheating mode→ignition mode→running mode.
During the preheating mode, denoted by “A” in
During the ignition mode, denoted by “B” in
If the fluorescent lamp 100 did not break down, no faulty- or erroneous-operation occurred, or there was no error in the circuit, the running mode allows the fluorescent lamp 100 to be driven at a constant frequency.
The running mode, denoted by “C” of
The described driving circuit is based on a zero-voltage switching control scheme. Generally, the zero-voltage switching indicates a specific switching technique capable of switching on the MOS transistor when a voltage difference between a drain terminal and a source terminal of the MOS transistor is almost zero, thereby minimizing the conduction loss and the EMI (Electro-Magnetic Interference).
Typically, the absence of zero-voltage switching indicates that the load resistance RL is extremely high or is not present. In this case, the resonance frequency of the resonance circuit is higher than the frequency of the running mode, such that the driving circuit is driven at a frequency lower than the resonance frequency of the resonance circuit.
In this case, the resonance circuit is operated similarly with the capacitive load (also called capacitor load), such that the current signal of the inductor L is leading the phase of the output voltage VO. As a result, a so-called “hard switching” occurs instead of zero-voltage switching.
During hard switching the output signal is changed by the switching operation and the switch is switched on by a maximum voltage. In this case, the conduction loss is high, and an abrupt current flow occurs in the switch, resulting in a high level of EMI. Also, the IC may be operated erroneously. Typically, most of the ballast ICs connect a capacitor CCP to an output terminal of the driving circuit and generate an auxiliary power-supply using the current signal of the capacitor CCP. This generates an operating voltage of the IC using the voltage signal of the auxiliary power-supply. The current signal of the capacitor CCP is determined by the rising slope of the output voltage VO. The slope of the output voltage VO is very steep, such that the current signal of the capacitor CCP increases and the increasing current signal encounters a high-voltage peak in the auxiliary power-supply unit. These can generate a high-frequency noise in the IC, such that the IC may be erroneously operated.
In
In
In
In
The above-mentioned interval Td is generally called a dead time. Generally, the ballast IC guarantees the above-mentioned dead time. However, if the dead time is not properly adjusted according to load states, the zero-voltage switching may be incorrectly performed. If a faulty- or erroneous-operation occurs, the system may not be protected from danger and harm, making it is impossible to guarantee the stability of the system.
In accordance with the present invention, the above and other objects can be and a second switching element comprising: a variable gain amplifier VGA connected to a first input terminal connected to a resistor, for generating an output current signal according to a resistance value of the resistor and a gain control signal; a preheating/ignition controller connected to a second input terminal connected to a capacitor, for generating an output current signal and an output voltage signal acting as the gain control signal according to a voltage of the second input terminal; an active zero-voltage controller for generating a hard-switching current signal and an active zero-voltage switching current signal, such that it adjusts the voltage of the second input terminal according to switching states of the first switching element and the second switching element; an oscillator for generating an oscillation signal upon receiving the output current signal from the variable gain amplifier VGA; and a dead-time controller for receiving the voltage signal of the second input terminal and an output signal of the oscillator, adjusting a dead time using the received signals, and at the same time generating driving signals of the first and second switching elements.
In some embodiments, the ballast integrated circuit IC further comprises: a voltage/current converter for converting a voltage signal of the first input terminal into a current signal, and transmitting the current signal to the variable gain amplifier VGA.
In some embodiments, the ballast integrated circuit IC further comprises: an edge detector for detecting a rising- or falling- edge generated at an output voltage of an output unit equipped with the first and second switching elements using a first or second terminal of an auxiliary power-supply unit capable of driving the first switching element, generating an edge detection signal, and transmitting the edge detection signal to the active zero-voltage switching controller.
In some embodiments, the edge detector includes a MOS transistor, connects a first terminal of the MOS transistor to the first or second terminal of the auxiliary power-supply unit, and allows a current signal proportional to a variation of the output voltage to flow in a parasitic capacitor arranged between the first terminal and the second terminal of the MOS transistor according to the variation of the output voltage.
In some embodiments, the edge detector includes: a MOS transistor including the parasitic capacitor arranged between the first terminal and the second terminal, connecting the first terminal to the first or second terminal of the auxiliary power-supply unit, and receiving an amount of the variation of the output voltage; a voltage/current converter for converting a current signal generated from the second terminal of the MOS transistor into a voltage signal; first and second comparators for generating a rising-edge detection signal and a falling-edge detection signal according to an output signal of the voltage/current converter, respectively; and an OR gate for receiving the rising-edge detection signal and the falling-edge detection signal, performing a logic OR operation on the received detection signals, and generating the OR-operation resultant signal as the edge detection signal.
In some embodiments, the edge detector includes a diode, connects a first terminal of the diode to a first or second terminal of the auxiliary power-supply unit, and allows a current signal proportional to a variation of the output voltage to flow in a parasitic capacitor arranged between the first terminal and the second terminal of the diode according to the variation of the output voltage.
In some embodiments, the edge detector includes: a diode including the parasitic capacitor arranged between the first terminal and the second terminal, connecting the first terminal to the first or second terminal of the auxiliary power-supply unit, and receiving an amount of the variation of the output voltage; a voltage/current converter for converting a current signal generated from the second terminal of the diode into a voltage signal; first and second comparators for generating a rising-edge detection signal and a falling-edge detection signal according to an output signal of the voltage/current converter, respectively; and an OR gate for receiving the rising-edge detection signal and the falling-edge detection signal, performing a logic OR operation on the received detection signals, and generating the OR-operation resultant signal as the edge detection signal.
In some embodiments, the active zero-voltage switching controller determines whether the first and second switching elements perform a hard switching operation or a zero-voltage switching operation by referring to the edge detection signal, whereby if the hard switching operation is determined, the active zero-voltage switching controller generates the hard-switching current signal, and if the active zero-voltage switching operation is determined, the active zero-voltage switching controller generates the active zero-voltage switching current signal.
In some embodiments, the ballast integrated circuit (IC) further comprises: a mode detector for determining whether a preheating mode and an ignition mode are completed by referring to the voltage of the second input terminal, and transmitting an enable signal to the active zero-voltage switching controller after detecting the completion of the preheating and ignition modes.
In some embodiments, the mode detector, if the voltage of the second input terminal is equal to or higher than a predetermined magnitude, recognizes a dead-time control mode, generates the enable signal, stops operation of the preheating/ignition controller, and activates operations of the active zero-voltage switching controller.
In some embodiments, the ballast integrated circuit (IC) further comprises: an under voltage lock-out (UVLO) unit for transmitting a reset signal to the mode detector if a power-supply voltage is equal to or less than a predetermined magnitude required for normal operations, thereby stopping operation of the ballast IC.
In some embodiments, the mode detector, if the voltage of the second input terminal is equal to or higher than a predetermined magnitude, recognizes a dead-time control mode, generates the enable signal, stops operation of the preheating/ignition controller, and activates operations of the active zero-voltage switching controller, determines if the voltage of the second input terminal is equal to or less than a predetermined magnitude, and finally stops operation of the ballast IC when the voltage of the second input terminal is equal to or less than a predetermined magnitude.
The above and other objects, features and other advantages of the present invention will be more clearly understood from the following detailed description taken in conjunction with the accompanying drawings, in which:
The present invention will be described in detail with reference to the annexed drawings. In the drawings, the same or similar elements are denoted by the same reference numerals. In the following description, a detailed description of known functions and configurations incorporated herein will be omitted for clairity.
The voltage/current converter 302 allows an external user to adjust the running-mode frequency using a resistor RRT connected in series to the first input terminal RT. The output current Io of the voltage/current converter 302 is controlled by the resistor RRT.
The Variable Gain Amplifier 304 receives the output current IO of the voltage/current converter 302, amplifies the received current IO using a gain determined by the output voltage VVGA of the preheating/ignition controller 308, and generates the output current IVGA.
The triangular oscillator 306 receives the output current IVGA of the VGA 304, performs charging/discharging of the capacitor CT connected to the triangular oscillator 306, and finally generates a clock signal CLK and an inverted clock signal
The preheating/ignition controller 308 receives an input signal via the second input terminal CPH. The capacitor CCPH is connected in series to the second input terminal CPH. The preheating/ignition controller 308 determines the preheating time and the ignition time by changing the current signal ICPH charged in the capacitor CCPH according to the capacitor CCPH voltage. The value of the current signal ICPH is reduced during the preheating mode, whereas it increases during the ignition mode.
The magnitude of the current signal ICPH is maintained during the dead-time control mode. The output voltage VVGA generated from the preheating/ignition controller 308 determines the gain AI of the VGA 304. The output voltage VVGA increases during the preheating mode, such that the output current IVGA of the VGA 304 is higher than the input current IO. In this case, the charging/discharging speed of the capacitor CT connected to the triangular oscillator 306 increases, such that the frequency of the clock signal (CLK) generated from the triangular oscillator 306 is higher than the resonance frequency.
If the voltage of the second input terminal CPH is in the ignition mode, the output voltage VVGA will be generated inversely proportional to the above-mentioned CPH voltage. In this case, the higher the CPH voltage, the lower the output current IVGA of the VGA 304. The higher the CPH voltage, the lower the charging/discharging speed of the capacitor CT connected to the triangular oscillator 306. Therefore, the lamp driving frequency is lower than the resonance frequency. If the CPH voltage is equal to or higher than a specific voltage, the running mode begins, and the output current IVGA of the VGA 304 is equal to the input current IO, such that the running mode is activated at the frequency determined by the first input terminal RT.
In conjunction, the preheating/ignition controller 308 is activated when the enable signal ENABLE of the mode detector 320 assumes a low level. If the enable signal ENABLE of the mode detector 320 assumes a high level, the preheating/ignition controller 308 does not adjust the current signal ICPH caused by the CPH voltage and the output current IVGA. In this case, the current signal ICPH is maintained at a predetermined value, and the output voltage VVGA is generated as a specific voltage capable of allowing the gain AI of the VGA 304 to be unity, “1”.
The active zero-voltage switching controller 310 is operated in the dead-time control mode, and determines a switching state using not only the input signal HIN of the high-side driver 316 and the input signal LIN of the low-side driver 318, but also the rising/falling information signal ED of the edge detector 312. The active zero-voltage switching controller 310 detects a quasi-ZVS (quasi zero-voltage switching) state and a hard-switching state HS, and discharges the capacitor CCPH using the quasi-ZVS current IQZVS and the hard-switching current IHS, thereby adjusting the CPH voltage of the second input terminal CPH.
The edge detector 312 is connected to the output terminals VS and VB. It detects the rising/falling edges of the output signal of the half-bridge inverter circuit, and generates the rising/falling information signal ED. The dead-time controller 314 adjusts the dead-time according to the CPH voltage of the second input terminal CPH. If the CPH voltage is low, the dead-time controller 314 increases the dead time. If the CPH voltage is high, the dead-time controller 314 reduces the dead time.
The high-side driver 316 generates the high-side output signal HO for driving the first switching element 121 upon receiving the high-side input signal HIN from the dead-time controller 314. The low-side driver 318 generates the low-side output signal LO for driving the second switching element 122 upon receiving the low-side input signal LIN from the dead-time controller 314.
The mode detector 320 detects the completion of the preheating and ignition modes using the voltage of the second input terminal CPH, and determines whether the dead-time control mode begins. The UVLO unit 322 detects the power-supply voltage VDD, and determines whether the ballast IC 300 is normally operated by referring to the power-supply voltage VDD. If the power-supply voltage VDD is equal to or less than a normal-operation voltage, the UVLO unit 322 generates the reset signal RESET, and stops operating the remaining circuits other than the UVLO unit 322 itself, such that it prevents faulty or erroneous operations from being generated.
The dead-time control mode (D) detects operation states of the first and second switching elements 121 and 122 using the ballast IC 300. If the zero-voltage switching is not performed, the dead time can be automatically controlled by the dead-time control mode (D).
If it is determined that the running mode begins, the first and second switching elements 121 and 122 are simultaneously switched off on the condition that a frequency is fixed to a predetermined value, such that the dead-time control mode (D) performs the active control operation capable of allowing the first and second switching elements 121 and 122 to perform the zero-voltage switching operation. If it is determined that the zero-voltage switching is not performed by referring to the operation states of the first and second switching elements 121 and 122, the dead time increases. If it is determined that the zero-voltage switching is not performed on the condition that the dead time maximally increases, the first and second switching elements 121 and 122 are switched off, and the ballast IC 300 enters the shut-down mode.
In some embodiments, the ballast IC 300 performs a variety of functions using the second input terminal CPH. There are three operation modes based on the CPH voltage. In the first mode, the CPH voltage can be in the range from 0V to 3V, and the enable signal ENABLE generated from the edge detector 312 of
In the first mode, as denoted by (A) in
In the second mode, as denoted by (B) in
In the third mode, as denoted by (C) in
If the dead-time control mode begins, the first or second mode does not begin although the CPH voltage is less than 5V, and the active zero-voltage switching control operation begins. If the CPH voltage is equal to or less than 2V, as denoted by (E) in
In some embodiments, the voltage of the capacitor CCPH connected to the second input terminal CPH is changed by a hard-switching current signal IHS generated from a source terminal of the first MOS transistor 123 and an active zero-voltage switching current IQZVS generated from a source terminal of the second MOS transistor 124. A gate terminal of the first MOS transistor 123 receives the hard-switching detection signal HSD acting as a first output signal of the active zero-voltage switching controller 310. A gate terminal of the second MOS transistor 124 receives the active zero-voltage switching detection signal QZD acting as a second output signal of the active zero-voltage switching controller 310. If each of the hard-switching current signal IHS and the active zero-voltage switching current signal IQZVS is 0V, the capacitor CCPH voltage increases by the output current signal ICPH of the preheating/ignition controller 308, such that the dead time is minimized. The hard-switching current signal IHS and the active zero-voltage switching current signal IQZVS are determined to be higher than the maximum value of the output current signal ICPH of the preheating/ignition controller 308. Therefore, if the hard-switching current signal HIS and the active zero-voltage switching current signal IQZVS are not equal to 0V, the CPH voltage of the second input terminal is reduced so that the dead time increases. As previously stated, if the CPH voltage drops to 2V or less, the process for implementing the zero-voltage switching condition by adjusting the dead time fails, and the system shuts down.
In
The sum HIN+LIN of the high-side input signal HIN and the low-side input signal LIN is applied to the D input terminal of the first D-flip-flop 410 and the clock input terminal of the second D-flip-flop 420. The edge detection signal ED is applied to the clock input terminal CLK of the first D-flip-flop 410 and the D input terminal of the second D-flip-flop 420. The Q output terminal of the first D-flip-flop 410 generates the hard switching detection signal HSD. The Q output terminal of the second D-flip-flop 420 generates the active zero-voltage switching detection signal QZD. In this case, the hard-switching detection signal HSD and the active zero-voltage switching detection signal QZD are adapted to generate the hard switching current signal IHs and the active zero-voltage switching current signal IQZVS received in the active zero-voltage switching controller 310. If the hard switching detection signal HSD assumes a high level, the hard switching current signal IHS is generated so that the voltage of the second input terminal CPH becomes lowered.
The edge detection signal ED is extracted during the above operations. The capacitor may be used to extract the edge signal of the output signal. The charging- or discharging-operation of the capacitor is performed during a short dead-time, and edges occur. In this case, a variation of the edge can be represented by the following equation 1:
Here IL is indicative of an inductor current. If the capacitor is connected to the output terminal at which the above-mentioned edge variation occurs, and the other output terminal is grounded, the current signal of the capacitor can be represented by the following equation 2:
The capacitor current I occurs at the output edge, and has a constant value. Therefore, if the capacitor current I is received in the voltage/current converter, a desired voltage signal capable of being generated at only the edge can be acquired. If the above-mentioned signal is detected by comparators, the rising/falling edges can be recognized, and the edge detection signal ED can also be acquired by the sum of the rising edge and the falling edge.
Generally, the capacitor capable of enduring high voltages is coupled to an external part in order to detect the edge signal. However, in the case of the parasitic capacitor Cgd of the high-voltage LDMOS transistor 500, the edge detection circuit occupies a small-sized area simultaneously with enduring the high voltage. The magnitude of the parasitic capacitor Cgd can be controlled by adjusting the size of the LDMOS transistor 500.
Edge information of the output signal should be applied to the drain terminal of the LDMOS transistor 500. For this purpose, the drain terminal of the LDMOS transistor 500 is connected to the output terminal VS or VB of the high-side driver 316 contained in the ballast IC 300. If transition occurs in the output signal, the current signal flows in the parasitic capacitor Cgd, and is then converted into a voltage signal by the current/voltage converter 510. If the output signal increases, the positive (+) voltage is applied to the current/voltage converter 510. Otherwise, if the output signal decreases, the negative (−) voltage is applied to the current/voltage converter 510. The output voltage is applied to the first and second comparators 521 and 522, and the edge detection signal ED is created by the OR gate 530.
Although the preferred embodiments of the present invention have been disclosed for illustrative purposes, those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims.
Number | Date | Country | Kind |
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10-2005-0117245 | Dec 2005 | KR | national |