Electricity: power supply or regulation systems – Output level responsive – Using a three or more terminal semiconductive device as the...
Reexamination Certificate
2001-10-31
2002-08-27
Vu, Bao Q. (Department: 2838)
Electricity: power supply or regulation systems
Output level responsive
Using a three or more terminal semiconductive device as the...
C323S284000, C323S222000
Reexamination Certificate
active
06441597
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to voltage regulator circuits. More particularly, the invention relates to the sensing of output inductor current delivered to a load by a buck-type DC-to-DC switched mode power converter.
2. Description of Related Art
Switched mode DC-to-DC power converters are commonly used in the electronics industry to convert an available direct current (DC) level voltage to another DC level voltage. A switched mode converter provides a regulated DC output voltage by selectively storing energy by switching the flow of current into an output inductor coupled to a load. A synchronous buck converter is a particular type of switched mode converter that uses two power switches, such as MOSFET transistors, to control the flow of current in the output inductor. A high-side switch selectively couples the inductor to a positive power supply while a low-side switch selectively couples the inductor to ground. A pulse width modulation (PWM) control circuit is used to control the gating of the high-side and low-side switches in an alternating manner. Synchronous buck converters generally offer high efficiency and high power density, particularly when MOSFET devices are used due to their relatively low on-resistance. Therefore, synchronous buck converters are advantageous for use in providing power to electronic systems having demanding power requirements, such as microprocessors that require a control voltage (V
cc
) of 1 to 1.5 volts with current ranging from 40 to 60 amps. For certain applications having especially high current load requirements, it is known to combine plural synchronous buck converters together in multi-phase configurations operated in an interleaf mode.
To regulate the performance of a synchronous buck converter, it is known to monitor the amount of current sent to the load. This information is important to protect the load from damage caused by excessive current, to ensure that sufficient current is delivered to the load in view of changing load conditions (i.e., controlling voltage “droop” caused by a step load), and to permit current sharing between phases of multi-phase configurations. One approach to measuring the load current is to include a sensing resistor in series with the output inductor and to monitor the voltage drop across the sensing resistor. The sensing resistor must have a resistance value large enough to keep the sensed voltage signal above the noise floor, as the voltage drop can be measured more accurately with a higher resistance value. A significant drawback of this approach is that the sensing resistor wastes the output energy and thereby reduces the efficiency of the synchronous buck converter. Moreover, the sensing resistor generates heat that must be removed from the system.
Another approach to measuring the load current is to place the sensing resistor in series with the drain of the high-side switch (i.e., MOSFET) and monitor the voltage drop across the sensing resistor as in the preceding approach. In this position, the amount of energy dissipated by the sensing resistor is substantially less than in the aforementioned position in series with the output inductor. A drawback of this approach is that the high-side switch changes state at a relatively high rate (e.g., greater than 250 KHz) and, as a result, the high-side switch current is discontinuous. When the high-side switch turns on, the current through the switch and the sensing resistor starts at zero and increases rapidly before settling and then returning to zero when the high-side switch turns off. The information obtained from sampling the voltage across the sensing resistor must therefore be utilized during a subsequent switching cycle, making it necessary to include “sample and hold” circuitry to store the sampled information from cycle to cycle. Not only does this add complexity to the converter, but there is also a time delay in regulating the output current that diminishes the stability of the converter.
Yet another approach to measuring the load current is to include a filter in parallel with the output inductor. The filter includes a resistor and a capacitor connected together in series. The signal passing through the output inductor has a DC component and an AC component. The AC component of the signal depends on the inductance and internal resistance values of the output inductor, as well as the resistance and capacitance of the current sensor. Through proper selection of the values of the resistor and capacitor, the instantaneous voltage across the capacitor can be made equal to the voltage across the DC resistance of the inductor and thereby proportional to the instantaneous current through the output inductor. Thus, the output inductor current can be sensed without dissipating the output energy by monitoring the voltage across the capacitor. A drawback of this approach is that the current sense signal has relatively small amplitude that is close to the noise floor and therefore highly susceptible to distortion due to noise.
It is also known to use the on-state resistance (R
DSON
) between source and drain terminals of one of the MOSFET switches as a sensing resistor. The advantage of this method is that there is no additional loss in energy by using the R
DSON
as the sensing resistor since this energy loss is already an inherent part of converter operation. Unfortunately, this method suffers from the same drawbacks as the aforementioned method of placing the sensing resistor in series with the drain of the high-side switch.
Accordingly, it would be desirable to provide a way to accurately sense the output inductor current delivered to a load by a buck-type DC-to-DC switched mode power converter without adversely affecting efficiency of the power converter.
SUMMARY OF THE INVENTION
The present invention overcomes these drawbacks of the prior art by providing a current sense circuit for a DC-to-DC power converter that accurately senses the output inductor current without adversely affecting efficiency of the power converter. The current sense circuit produces a current sense signal having amplitude sufficiently above the noise floor so that accurate load control of the power converter is achieved.
In an embodiment of the invention, the DC-to-DC power converter includes at least one power switch connected to an input voltage source. At least one phase sensing switch is connected to the input voltage source in parallel with the at least one power switch. A pulse width modulation circuit provides common control pulses for the at least one power switch and the at least one phase sensing switch responsive to a current sense signal. An output inductor is connected to the at least one power switch and to a load. A current sensor is coupled to the output inductor and providing the current sense signal to the pulse width modulation circuit corresponding to current passing through an internal DC resistance of the output inductor. The current sensor further includes a filter that includes an on-state resistance of the at least one power switch. The current sensor further includes a second filter adapted to remove noise from the current sense signal when the at least one phase sensing switch and the at least one power switch change state.
More particularly, the at least one power switch further comprises a high-side power switch connected to the power input and a low-side power switch connected to ground. The high-side power switch and the low-side power switch are connected together to define a power phase node therebetween. The output inductor is connected to the power phase node. The at least one phase sensing switch further comprises a high-side phase sensing switch connected to the power input and a low-side phase sensing switch connected to ground. The high-side phase sensing switch and the low-side phase sensing switch are connected together to define a signal phase node therebetween. The filter is connected to the signal phase node. The filter further comprises an on-state resistance of the high-side po
O'Melveny & Myers LLP
Semtech Corporation
Vu Bao Q.
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