BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a gate driver and a related output voltage control method, and more particularly, to a gate driver and a related output voltage control method capable of reducing an output voltage and a current slew rate of the gate driver.
2. Description of the Prior Art
A gate driver of a driving integrated circuit (IC) of a conventional liquid-crystal display (LCD) usually adopts Metal-Oxide-Semiconductor Field-Effect Transistor (MOSFET) switches to drive GOA (Gate on Array) circuits and multiplexers on the panel, which can easily adjust a driving ability. However, when the MOSFET switch is turned on, the MOSFET switch is switched from open (e.g. equivalent to a degree more than millions of ohm) to be conducted (e.g. equivalent to a degree under of thousands of ohm), an instantaneous peak current is generated due to a sudden change of resistance, and the instantaneous peak current is utilized for charging or discharging resistor-capacitor loops on the panel to turn on/off the switches on the panel.
According to electromagnetic wave theory, source, path and antenna are three critical factors to generate electromagnetic waves. The above instantaneous peak current provides the source, the resistor-capacitor loops from the IC to the panel provide the path, and a stacking structure of the panel provides a resonator for the antenna, the electromagnetic waves are therefore generated and emitted around the panel, which generates issues of electromagnetic interference and affects the communication bands.
Therefore, improvements are necessary to the prior art.
SUMMARY OF THE INVENTION
Therefore, the present invention provides a gate driver and a related output voltage control method to limit an output current of the gate driver, and to reduce an output slew rate and a peak current slew rate of the gate driver.
An embodiment of the present invention discloses a gate driver for a panel, wherein the gate driver comprises at least an output channel unit, each of the output channel unit comprises a first driving unit; a second driving unit; a first current limit circuit, coupled to the first driving unit, configured to control an output current according to an output voltage of the gate driver to limit an output current slew rate of the gate driver; and a second current limit circuit, coupled to the second driving unit, configured to control the output current according to the output voltage of the gate driver to limit the output current slew rate of the gate driver.
Another embodiment of the present invention discloses a gate driver, for a panel, wherein the gate driver comprises at least an output channel unit, each of the output channel unit comprises a first driving unit; a second driving unit; and a current limit circuit, respectively coupled to the first driving unit and the second driving unit via a first switch and a second switch, configured to control an output current of the gate driver according to an output voltage of the gate driver, such that the first driving unit and the second driving unit are equally controlled to limit an output current slew rate of the gate driver.
Another embodiment of the present invention discloses an output voltage control method, for a gate driver of a panel, wherein the gate driver comprises at least an output channel unit, each of the output channel unit comprises a first driving unit, a second driving unit, a first current limit circuit and a second current limit circuit, the output voltage control method comprises controlling an output current of the gate driver according to an output voltage of the gate driver to limit an output current slew rate of the gate driver
Another embodiment of the present invention discloses an output voltage control method, for a gate driver of a panel, wherein the gate driver comprises at least an output channel unit, each of the output channel unit comprises a first driving unit, a second driving unit and a current limit circuit, the output voltage control method comprises controlling an output current of the gate driver according to an output voltage of the gate driver, such that the first driving unit and the second driving unit are equally controlled to limit an output current slew rate of the gate driver.
These and other objectives of the present invention will no doubt become obvious to those of ordinary skill in the art after reading the following detailed description of the preferred embodiment that is illustrated in the various figures and drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a schematic diagram of a gate driver according to an embodiment of the present invention.
FIG. 2 is a schematic diagram of an output voltage of the gate driver according to an embodiment of the present invention.
FIG. 3 is a schematic diagram of a comparison of an output current slew rate of the gate driver according to an embodiment of the present invention versus a conventional technique.
FIG. 4 to FIG. 5 are schematic diagrams of another gate driver according to an embodiment of the present invention.
FIG. 6 is a schematic diagram of a comparison of a variation trend of voltages of a driving unit according to an embodiment of the present invention versus a conventional technique.
FIG. 7 to FIG. 10 are schematic diagrams of another gate driver according to an embodiment of the present invention.
FIG. 11 is a schematic diagram of an instantaneous current of an output voltage of the gate driver according to an embodiment of the present invention.
FIG. 12 is a schematic diagram of another gate driver according to an embodiment of the present invention.
FIG. 13 is a schematic diagram output voltages and current peaks of a conventional gate driver.
FIG. 14 is a schematic diagram of output voltages and current peaks of the gate driver according to an embodiment of the present invention.
DETAILED DESCRIPTION
Please refer to FIG. 1, which is a schematic diagram of a gate driver 10 according to an embodiment of the present invention. The gate driver 10 includes at least an output channel unit 11_1, 11_2 . . . 11_n, each output channel unit 11_1, 11_2 . . . 11_n includes a first driving unit 102, a second driving unit 104, a first current limit circuit 106 and a second current limit circuit 108. The gate driver 10 may be utilized on a panel of a liquid-crystal display (LCD), for performing charging or discharging loadings, e.g. resistors or capacitor circuits on the panel. The first driving unit 102 and the second driving unit 104 may be respectively a switch of a gate output control circuit 110, e.g. a Metal-Oxide-Semiconductor Field-Effect Transistor (MOSFET) switch, in FIG. 1, the first driving unit 102 is a P-type MOSFET switch, the second driving unit 104 is an N-type MOSFET switch.
An output voltage Vout of an output terminal OUT of each output channel unit 11_1, 11_2 . . . 11_n of the gate driver 10 varies between a first voltage VL and a second voltage VH, as shown in FIG. 2, to charge or discharge the loadings on the panel, wherein the first driving unit 102 (i.e. the P-type MOSFET switch) is utilized for outputting the second voltage VH, the second driving unit 104 (i.e. the N-type MOSFET switch) is utilized for outputting the first voltage VL. The first current limit circuit 106 may be a P-type current mirror, configured to control an output current VH current of each output channel unit 11_1, 11_2 . . . 11_n of the gate driver 10, according to the output voltage Vout of each output channel unit 11_1, 11_2 . . . 11_n of the gate driver 10 to limit an output current slew rate of the gate driver 10. The second current limit circuit 108 may be an N-type current mirror, configured to control an output current VL current of each output channel unit 11_1, 11_2 . . . 11_n of the gate driver 10, according to the output voltage Vout of each output channel unit 11_1, 11_2 . . . 11_n of the gate driver 10 to limit the output current slew rate of the gate driver 10.
In other words, when the output voltage Vout of one of the output channel units 11_1, 11_2 . . . 11_n of the gate driver 10 is varied from the first voltage VL to the second voltage VH, the first current limit circuit 106 can limit a highest output current of the output current VH current to limit the output current slew rate of the gate driver 10; in contrast, when the output voltage Vout of the gate driver 10 is varied from the second voltage VH to the first voltage VL, the second current limit circuit 108 may limit a highest output current of the output current VL current to limit the output current slew rate of the gate driver 10. Therefore, the gate driver 10 according to an embodiment of the present invention can limit the output current slew rate of the gate driver 10 by the first current limit circuit 106 and the second current limit circuit 108.
As shown in FIG. 3, compared to a current slew rate of the conventional gate driver, a larger peak current is generated when ascending or descending, the current slew rate of the gate driver according to the present invention is smaller when the output voltage Vout is varied from the first voltage VL to the second voltage VH; similarly, the current slew rate of the gate driver 10 according to the present invention is smaller that of the conventional gate driver, when the output voltage Vout is varied from the second voltage VH and the first voltage VL.
In another embodiment, FIG. 4 is a schematic diagram of a gate driver 40 according to an embodiment of the present invention. The gate driver 40 includes at least one of output channel unit 41_1, 41_2 . . . 41_n, each output channel unit 41_1, 41_2 . . . 41_n includes a first driving unit 402, a second driving unit 404, a first current limit circuit 406, a second current limit circuit 408, a first previous-stage buffer 410 and a second previous-stage buffer 412. The gate driver 40 may be one of variations of the embodiment of the gate driver 10. The gate driver 40 may be utilized on a panel of a liquid-crystal display (LCD), for performing charging or discharging loadings, e.g. resistors or capacitor circuits on the panel. The first driving unit 402 and the second driving unit 404 of each output channel unit 41_1, 41_2 . . . 41_n of the gate driver 40 may respectively be a transistor. In the embodiment of FIG. 4, the first driving unit 402 is a P-type MOSFET switch, the second driving unit 404 is an N-type MOSFET switch. The first current limit circuit 406 may be an N-type current mirror; the second current limit circuit 408 may be a P-type current mirror. Different to the gate driver 10, each output channel unit 41_1, 41_2 . . . 41_n of the gate driver 40 further includes the first previous-stage buffer 410 and the second previous-stage buffer 412, wherein the first previous-stage buffer 410 further includes driving switches 410_M1, 410_M2 for slowing down a voltage descending slope of an output voltage Vout of the output channel units 41_1, 41_2 . . . 41_n with the first previous-stage buffer 410 to limit the output current slew rate of each output channel unit 41_1, 41_2 . . . 41_n of the gate driver 40. The second previous-stage buffer 412 further includes driving switches 412_M1, 412_M2, for slowing down a voltage ascending slope of the output voltage Vout of each output channel unit 41_1, 41_2 . . . 41_n of the gate driver 40 with the second previous-stage buffer 412 to limit the output current slew rate of the gate driver 40.
Since the output voltage Vout of each output channel unit 41_1, 41_2 . . . 41_n of the gate driver 40 is varied between the first voltage VL and the second voltage VH, as shown in FIG. 2, to charge and discharge the loadings on the panel, the first driving unit 402 (i.e. the P-type MOSFET switch) may be utilized for outputting the second voltage VH, and the second driving unit 404 (i.e. the N-type MOSFET switch) may be utilized for outputting the first voltage VL. Therefore, when the output voltage Vout of each output channel unit 41_1, 41_2 . . . 41_n of the gate driver 40 is raised from the first voltage VL to the second voltage VH, the first driving unit 402 is activated to pull a high voltage VGH of a gate terminal Vpg to a low voltage VGL, and the first current limit circuit 406 of the output channel units 41_1, 41_2 . . . 41_n may limit a pull-low ability of the gate terminal Vpg of the first previous-stage buffer 410, such that the first driving unit 402 cannot be turned on too quickly, which reduces the voltage descending slope of the gate terminal Vpg and limits a charging peak current slew rate of the first driving unit 402.
Similarly, when the output voltage Vout of each output channel unit 41_1, 41_2 . . . 41_n of the gate driver 40 is pulled from the second voltage VH to the first voltage VL, the second driving unit 404 is activated, a gate terminal Vng of the second driving unit 404 is pulled from the low voltage VGL to the high voltage VGH, the second current limit circuit 408 of each output channel unit 41_1, 41_2 . . . 41_n of the gate driver 40 may limit a pull-high ability of the second previous-stage buffer 412, such that the second driving unit 404 cannot be turned on too quickly, which reduces the voltage ascending slope of the gate terminal Vng and limits a charging peak current slew rate of the second driving unit 404.
In another embodiment, please refer to FIG. 5, which is a schematic diagram of a gate driver 50 according to an embodiment of the present invention. The gate driver 50 may be one of alternative embodiments of the gate driver 10. The gate driver 50 includes at least one of output channel unit 51_1, 51_2 . . . 51_n, each output channel unit 51_1, 51_2 . . . 51_n includes a first driving unit a first driving unit 502, a second driving unit 504, a first passive circuit 506, a second passive circuit 508, a first previous-stage buffer 510 and a second previous-stage buffer 512. The gate driver 50 may be utilized on a panel of a liquid-crystal display (LCD), for performing charging or discharging loadings, e.g. resistors or capacitor circuits on the panel. The first driving unit 502 and the second driving unit 504 may respectively be a switch. In the embodiment of FIG. 5, the first driving unit 502 is a P-type MOSFET switch and the second driving unit 504 is an N-type MOSFET switch. Different to the gate driver 10, each output channel unit 51_1, 51_2 . . . 51_n of the gate driver 50 further includes the first passive circuit 506 and the second passive circuit 508, wherein the first passive circuit 506 may be a resistor-capacitor circuit with a resistor Rp and a capacitor Cp for slowing down a voltage descending slope of the output voltage Vout of the output channel units 51_1, 51_2 . . . 51_n with the first previous-stage buffer 510 to limit the output current slew rate of the gate driver 50. The second passive circuit 508 may be a resistor-capacitor circuit with a resistor Rn and a capacitor Cn for slowing down a voltage ascending slope of the output voltage Vout of the output channel units 51_1, 51_2 . . . 51_n with the second previous-stage buffer 512 to limit the output current slew rate of the gate driver 50.
In other words, the first passive circuit 506 of each output channel unit 51_1, 51_2 . . . 51_n of the gate driver 50 may limit a pull-low ability of the first previous-stage buffer 510, such that the first driving unit 502 cannot be turned on too quickly, which reduces a voltage descending slope of a gate terminal Vpg and limits a charging peak current slew rate of the first driving unit 502. Similarly, the second passive circuit 508 of each output channel unit 51_1, 51_2 . . . 51_n of the gate driver 50 may limit a pull-high ability of the second previous-stage buffer 512, such that the second driving unit 504 cannot be turned on too quickly, which reduces the voltage ascending slope of a gate terminal Vng and limits a charging peak current slew rate of the second driving unit 504.
FIG. 6 illustrates a voltage variation trend of the gate terminal Vpg and the gate terminal Vng. Solid lines in FIG. 6 illustrate voltages of the gate terminal Vpg and the gate terminal Vng without the first passive circuit 506, the second passive circuit 508, dash lines in FIG. 6 illustrate voltages of the gate terminal Vpg and the gate terminal Vng of the gate driver 50 according to an embodiment of the present invention. As can be known from FIG. 6, the voltage variations of the gate terminal Vpg and the gate terminal Vng according to an embodiment of the present invention are smoother than those without the first passive circuit 506, the second passive circuit 508, and the charging peak current slew rate of corresponding driving unit is reduced.
Since the gate driver usually includes multiple output channel units, in another embodiment, different output channel units may be connected to an identical current limit circuit.
Please refer to FIG. 7, which is a schematic diagram of a gate driver 70 according to an embodiment of the present invention. The gate driver 70 includes at least one of output channel unit 71_1, 71_2 . . . 71_n, each output channel unit 71_1, 71_2 . . . 71_n includes a first driving unit 702, a second driving unit 704, transistors M1, M2, a current limit circuit 706 and a gate output control circuit 708. The gate driver 70 may be utilized on a panel of a liquid-crystal display (LCD), for performing charging or discharging loadings, e.g. resistors or capacitor circuits on the panel. The first driving unit 702 may be a driving switch, the second driving unit 704 may be a driving switch, wherein the driving switch may be an MOSFET switch, the gate output control circuit 708 may control the first driving unit 702, the second driving unit 704 to determine the output voltage Vout of the output terminal OUT.
In the embodiment of FIG. 7, the first driving unit 702 is a P-type MOSFET switch, the second driving unit 704 is an N-type MOSFET switch. The current limit circuit 706 is a current mirror, which includes transistors M3, M4, and is coupled to each output channel unit 71_1, 71_2 . . . 71_n of the gate driver 70 in FIG. 7. Take the output channel unit 71_1 in FIG. 7 as an example, the current limit circuit 706 and the transistor M1 of the output channel unit 71_1 form a current mirror, and the current limit circuit 706 and the transistor M2 of the output channel unit 71_1 form a current mirror to limit an output current of the output channel unit 71_1 of the gate driver 70. Similarly, the output channel units 71_2 . . . 71_n and the current limit circuit 706 may respectively form the current mirror circuits to limit the output currents of the output channel units 71_2 . . . 71_n of the gate driver 70. That is, each output channel unit 71_1, 71_2 . . . 71_n of the gate driver 70 is connected to the current limit circuit 706 and shares the identical current limit circuit 706.
Since the output voltage Vout of each output channel unit 71_1, 71_2 . . . 71_n of the gate driver 70 varies between the first voltage VL and the second voltage VH, as shown in FIG. 2, to charge or discharge the loadings on the panel, the current limit circuit 706 is configured to control the output currents VH current, VL current of each output channel unit 71_1, 71_2 . . . 71_n of the gate driver 70 according to the output voltage Vout of each output channel unit 71_1, 71_2 . . . 71_n of the gate driver 70, such that the first driving unit 702 and the second driving unit 704 of each output channel unit 71_1, 71_2 . . . 71_n are equally controlled to limit an output current slew rate of the gate driver 70.
In other words, when the output voltage Vout of the output channel units 71_1, 71_2 . . . 71_n of the gate driver 70 is varied from the first voltage VL to the second voltage VH, the current limit circuit 706 and the transistor M1 of each output channel unit 71_1, 71_2 . . . 71_n may respectively forma current mirror to limit a highest output current of the output current VH current to further limit the output current slew rate of the gate driver 70; in contrast, when the output voltage Vout of the output channel units 71_1, 71_2 . . . 71_n of the gate driver 70 is varied from the second voltage VH to the first voltage VL, the current limit circuit 706 and the transistor M2 may be respectively form a current mirror with each output channel unit 71_1, 71_2 . . . 71_n to limit a highest output current of the output current VL current to further limit the output current slew rate of the gate driver 70. Therefore, the gate driver 70 can limit the output current slew rate of the gate driver 70 with the common current limit circuit 706.
In another embodiment, FIG. 8 is a schematic diagram of a gate driver 80 according to an embodiment of the present invention. The gate driver 80 includes at least one of output channel unit 81_1, 81_2 . . . 81_n, each output channel unit 81_1, 81_2 . . . 81_n includes a first driving unit 802, a second driving unit 804, the transistors M1, M2, a current limit circuit 806, a first previous-stage buffer 810 and a second previous-stage buffer 812. The gate driver 80 may be one of alternative embodiments of the gate driver 70. The gate driver 80 may be utilized on a panel of a liquid-crystal display (LCD), for performing charging or discharging loadings, e.g. resistors or capacitor circuits on the panel. The first driving unit 802 and the second driving unit 804 may be respectively a driving switch. In the embodiment of FIG. 8, the first driving unit 802 is a P-type MOSFET switch, the second driving unit 804 is an N-type MOSFET switch. The first previous-stage buffer 810 and the second previous-stage buffer 812 may control the first driving unit 802, the second driving unit 804 to determine the output voltage Vout of the output terminal OUT. The current limit circuit 806 is a current mirror, which includes transistors M3, M4, and is coupled to the gate driver 80 in FIG. 8. In FIG. 8, the current limit circuit 806 may form a current mirror with the transistor M1 of each output channel unit 81_1, 81_2 . . . 81_n, and the current limit circuit 806 may form a current mirror with the transistor M2 of each output channel unit 81_1, 81_2 . . . 81_n to limit output currents of each output channel unit 81_1, 81_2 . . . 81_n of the gate driver 80. That is, each output channel unit 81_1, 81_2 . . . 81_n of the gate driver 80 connects to the current limit circuit 806 to share the common current limit circuit 806.
Different to the gate driver 70, each output channel unit 81_1, 81_2 . . . 81_n of the gate driver 80 further includes the first previous-stage buffer 810 and the second previous-stage buffer 812.
Take the output channel unit 81_1 as an example, the first previous-stage buffer 810 may include driving switches 810 M1, 810 M2 for slowing down a voltage descending slope of a first gate terminal Vpg of the first driving unit 802 with the current limit circuit 806 to limit the output current slew rate of the gate driver 80. The second previous-stage buffer 812 may include driving switches 812_M1, 812_M2 for slowing down a voltage ascending slope of a second gate terminal Vng of the second driving unit 804 with the current limit circuit 806 to limit the output current slew rate of the gate driver 80.
Therefore, each output channel unit 81_1, 81_2 . . . 81_n, connecting to an N2 node, of the gate driver 80 shares the common current limit circuit 806 to limit a pull-low ability of the first previous-stage buffer 810 of the output channel units 81_1, 81_2 . . . 81_n and to limit a charging peak current slew rate of the first driving unit 802 of each output channel unit 81_1, 81_2 . . . 81_n. Similarly, the current limit circuit 806 may limit a pull-high ability of the second previous-stage buffer 812 of the output channel units 81_1, 81_2 . . . 81_n connecting to a P2 node to limit a charging peak current slew rate of the second driving unit 804 of each output channel unit 81_1, 81_2 . . . 81_n.
In another embodiment, feedback loop circuits may be added to the above gate drivers. Please refer to FIG. 9, which is a schematic diagram of a gate driver 90 according to an embodiment of the present invention. The gate driver 90 only illustrates an output terminal and a previous-stage buffer of the gate driver 90. As shown in FIG. 9, the output terminal of the gate driver 90 further includes capacitors Cp, Cn to form feedback loops FB p, FB n, such that when the output voltage Vout is raised from the first voltage VL to the second voltage VH, a negative feedback loop of the feedback loop FB p generates a negative suppressing signal to suppress a voltage variation slope (i.e. a voltage descending slope) of a gate terminal Vpg to reduce a peak current slew rate of the gate driver 90.
Similarly, when the output voltage Vout is reduced from the second voltage VH to the first voltage VL, a negative feedback loop of the feedback loop FB n generates a negative suppressing signal to suppress a voltage variation slope (i.e. a voltage ascending slope) of a gate terminal Vng to reduce a peak current slew rate of the output terminal of the gate driver 90.
Alternatively, in another embodiment, the driving units of the gate drivers according to the embodiments of the present invention may be turned on with multiple stages. Please refer to FIG. 10, which is a schematic diagram of a gate driver 100 according to an embodiment of the present invention. FIG. 10 only illustrates an output terminal and a gate output control circuit of the gate driver 100. In FIG. 10, switches of the gate output control circuit may be implemented by multiple switches Pgate_1-Pgate_3, Ngate_1-Ngate_3 with smaller area in hardware, e.g. a ratio of implemented areas of the switches Pgate_1, Pgate_2, Pgate_3 on an IC is 1:2:3, wherein the switches Pgate_1-Pgate_3, Ngate_1-Ngate_3 may be implemented by transistors.
In detail, please refer to FIG. 11, is a schematic diagram of an instantaneous current of an output current VH current of the gate driver 100 according to an embodiment of the present invention. When the output voltage Vout is varied from the first voltage VL to the second voltage VH, and the switches Pgate_1-Pgate_3 are turned on with multiple stages, the switch Pgate_1 is firstly conducted (stage 1), and then the switches Pgate_1, Pgate_2 are conducted (stage 2), and the switches Pgate_1-Pgate_3 are conducted lastly (stage 3).
Since a resistance of the switch Pgate_1 is larger when conducted, the instantaneous current is smaller, and a difference between the output voltage and a target voltage is smaller than in the stage 2 and stage 3, such that the instantaneous current is reduced. Therefore, as shown in FIG. 11, compared to a conventional switch of the gate output control circuit with only one stage, the gate driver 100 according to an embodiment of the present invention may reduce a current variation rate and a voltage output slope of the output terminal OUT, and to reduce a phenomenon of electromagnetic interference.
Similarly, when the output voltage Vout is varied from the second voltage VH to the first voltage VL, the switches Ngate_1-Ngate_3 are sequentially conducted to reduce the current variation rate and the voltage output slope of the output terminal OUT, and to reduce a phenomenon of electromagnetic interference.
In addition to the implementation of multiple switches with different areas on the IC, resistors with different resistances may be serial connected to the switches Pgate_1-Pgate_3, the switches Ngate_1-Ngate_3 to achieve the identical effects, and not limited to the above embodiment.
Compared to the conventional gate driver with a single output channel connecting two terminals of the loading of the panel, in an embodiment, a gate driver according to an embodiment of the present invention may output identical signals to the two terminals of the loading of the panel for driving, which reduces occurrence times of the instantaneous current, and reduces the electromagnetic energy.
Please refer to FIG. 12, which is a schematic diagram of a gate driver 1200 according to an embodiment of the present invention. The gate driver 1200 includes a left channel gate driving unit 1200_L and a right channel gate driving unit 1200_R, respectively coupled to a left side and a right side of a panel. Since the left channel gate driving unit 1200_L and the right channel gate driving unit 1200_R are activated with a time division method by the gate driver 1200 to drive the left side and the right side of the panel, a variation of an instantaneous current of the panel loading is reduced.
Moreover, as shown in FIG. 13, eight peak currents are generated in four variation periods of the output voltage Vout of the conventional gate driver, if the two sides of the panel loading are simultaneously driven.
In comparison, as shown in FIG. 14, when the left channel gate driving unit 1200_L and the right channel gate driving unit 1200_R are activated in turns to drive the panel loading, an occurrence times of the peak currents of the left channel and the right channel of the panel is reduced to four times in four variation periods of the output voltage of the gate driver 1200. In addition, an energy distribution of current is reduced and the electromagnetic energy is reduced.
In summary, the present invention provides a gate driver and a related output voltage control method, which limits an output current of the gate driver and further reduces an output slew rate and a peak current slew rate of the gate driver.
Those skilled in the art will readily observe that numerous modifications and alterations of the device and method may be made while retaining the teachings of the invention. Accordingly, the above disclosure should be construed as limited only by the metes and bounds of the appended claims.