Voltage regulator with improved transient response

Details Voltage regulator with improved transient response Voltage regulator with improved transient response

2000-08-15

2001-11-20

Wong, Peter S. (Department: 2838)

Electricity: power supply or regulation systems

Input level responsive

Using a linearly acting final control device

C323S274000, C323S299000

Reexamination Certificate

active

06320363

ABSTRACT:

BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to voltage protection circuits and, more specifically, to a voltage regulator with improved transient response capable of maintaining voltage within a predetermined range, which can be used as a voltage protection circuit.
2. Description of the Related Art
Excessive voltage can cause detrimental effects in electric appliances and electronic circuits. For example, lithium based batteries, including Lithium-Ion batteries and Lithium-Polymer batteries can be sensitive to and damaged by excessive voltage.
Excessive voltage can come from various external sources in different forms. Transient voltage spikes from external sources are one example. A transient voltage spike can be caused, for example, by an electrostatic discharge (ESD) event. Transient voltage spikes can cause damages in electronic circuits such as overcharging failure.
Currently, several approaches can be utilized to reduce or control impacts of external transient voltage events on various electronic circuits, in particular, semiconductor circuits. One approach widely used in the field of integrated circuit (IC) design is to clamp transient voltages on the inputs of the IC pins to protect the internal IC circuits from external voltage transient events. To do so, a shunt voltage regulator control circuit may be utilized for voltage protection. One example of a shunt voltage regulator is disclosed in U.S. patent application Ser. No. 09/545,135, entitled “Shunt Voltage Regulator with Self-Contained Thermal Crowbar Safety Protection,” filed Apr. 7, 2000, which is hereby incorporated by reference for background purposes only. If a shunt voltage regulator is sufficiently fast and of sufficient bandwidth, the shunt voltage regulator can rapidly clamp all external voltage and current transients imposed therein from external sources. In this way, a circuit incorporating such a shunt voltage regulator can protect itself from external voltage transients.
FIG. 1
shows a simple prior art shunt voltage regulator circuit
100
(different from that disclosed in the aforementioned co-pending application). The circuit
100
includes a transistor
110
(such as a metal oxide semiconductor field effect transistor) having a first pole electrically coupled to the first node
102
, a second pole electrically coupled to the second node
104
and a gate. The transistor
110
is capable of controlling an electrical current flowing from the first node
102
to the second node
104
, i.e., ground, as a function of a voltage at its gate, which is also referred to herein as a controlling port. A voltage reference
150
generates a signal that has a predetermined potential difference from the second node
104
. An amplifier
120
, having a first input electrically coupled to the first node
102
and a second input electrically coupled to the signal from the voltage reference
150
, generates an output electrically coupled to the gate of the transistor
110
. The output of the amplifier
120
is thus a function of a voltage difference between the first node
102
and the second node
104
.
The voltage regulator circuit
100
can be utilized in many applications. For example, the voltage regulator circuit
100
can be adapted to prevent overcharging of a battery
170
when the battery
170
is subjected to unusually high or excessive voltages, such as a voltage transient spike I. When an unusually high voltage is detected across the battery
170
, the voltage regulator
100
increases the current bypassing the battery
170
through the first and second poles of the transistor
110
, thereby reducing the voltage across the battery
170
. Thus, by adjusting the current that bypasses the battery
170
, the circuit
100
keeps the voltage across the nodes of the battery
170
within a desired range.
To achieve the desired protection, a shunt voltage regulator circuit should be optimized with respect to its circuit characteristics for fast response and wide bandwidth. One advantage for a voltage regulator circuit having fast response is that the voltage regulator circuit may protect itself, in addition to circuits the voltage regulator circuit may be adapted to protect, from excessive voltage transients. However, as is known in the art, such optimization may result in a shunt voltage regulator circuit that has poor steady state control accuracy. For example, in applications related to battery protection, this can result in an undesirable degradation of battery cell protection performance. On the other hand, a shunt voltage regulator circuit that is optimized for best steady state accuracy, as is required for good cell protection, is likely not to have the fast response and wide bandwidth required to adequately protect itself from excessive voltage transients.
There is therefore a need for a shunt voltage regulator that can have steady state control accuracy and the fast response and wide bandwidth with respect to external voltage transients.


REFERENCES:
patent: 4390828 (1983-06-01), Converse et al.
patent: 4536699 (1985-08-01), Baker
patent: 4580090 (1986-04-01), Bailey et al.
patent: 4705572 (1987-11-01), Melbert
patent: 4814687 (1989-03-01), Walker

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