Miscellaneous active electrical nonlinear devices – circuits – and – Specific identifiable device – circuit – or system – With specific source of supply or bias voltage
Reexamination Certificate
2002-02-21
2004-04-06
Callahan, Timothy P. (Department: 2816)
Miscellaneous active electrical nonlinear devices, circuits, and
Specific identifiable device, circuit, or system
With specific source of supply or bias voltage
C363S059000
Reexamination Certificate
active
06717459
ABSTRACT:
FIELD OF THE INVENTION
The present invention relates to a charge pump, and more particularly to a charge pump adapted to be included on an integrated circuit for converting a supplied voltage to a desired voltage.
BACKGROUND OF THE INVENTION
It is often useful to provide a voltage to a component on an integrated circuit chip that exceeds a voltage supplied to the chip. Elevated voltages are employed, for example, on DRAM integrated circuits for boosted wordline voltages and negative substrate bias voltages, and for writing and erasing EEPROMS. By generating requisite elevated voltages on the integrated circuit itself, the need for one or more external power supplies is eliminated.
On an integrated circuit, inductors are more difficult to implement than capacitors. Thus, where various voltages are needed on an integrated circuit, it is advantageous to use a capacitive charge pump capable of transforming voltage without the use of inductors.
Two important parameters of charge pump operation are capacity and efficiency. Capacity is a measure of how much current a pump can continuously supply. Capacity is determined in part by the size of a bootstrap capacitor and operating frequency. Efficiency is a measure of how much charge, or current, is wasted during each pump cycle. A typical prior art integrated circuit charge pump is 30-50% efficient. This translates into a loss of 2-3 milliamps of supply current for every milliamp of pump output current.
FIG. 1
shows a conventional single-phase charge pump
10
adapted to receive a first voltage Vcc
12
as an input and provide a second higher voltage as an output. The single phase charge pump includes an inverter
14
having an input
16
adapted to receive an oscillating signal. Also included is a bootstrap capacitor
20
having a driving side
22
and a driven side
24
. The inverter is adapted to connect the driving side
22
of capacitor
20
alternately between VCC
12
and ground
30
. The driven side
24
of the bootstrap capacitor is operatively connected through a first diode
34
to a source of supply voltage Vcc
12
, and through a second diode
36
to a load
38
. The load
38
is operatively connected between the second diode
36
and ground
30
.
Assuming ideal components, the circuit of
FIG. 1
operates as follows: at a first time, an input signal applied at input
16
of the inverter
14
is high, causing the inverter to connect the driving side
22
of capacitor
20
to ground
30
. Responsively, current flows through the first diode
34
, transporting electrical charge from the source of supply voltage Vcc
12
to the driven side
24
of the bootstrap capacitor
20
. As charge accumulates on the driven side
24
of the bootstrap capacitor
20
, voltage Vcc
12
develops across the capacitor. At a later time, the signal at the input
16
of the inverter
14
goes low. This connects the driving side
22
of the capacitor
20
to the source of supply voltage Vcc
12
. Charge flows into the driving side
22
of the capacitor
20
, and the voltage on the driven side
24
of the capacitor rises to 2 Vcc with respect to ground in response. Current flows through the second diode
36
to apply a voltage of 2 Vcc to an input
40
of the load
38
. After the voltage on the driving side of the bootstrap capacitor has risen to Vcc, the signal at the input
16
of inverter
14
transitions again causing the voltage on the driving side
22
of capacitor
20
to go to ground. The charge pump cycle is then complete. With repeated cycles, a pulsed voltage of more or less 2 Vcc can be maintained across the load.
As actually constructed, the single-phase charge pump circuit of
FIG. 1
is relatively inefficient, and it produces an output voltage that varies significantly with time. Also, for non-ideal components, the output voltage is limited to two times Vcc less at least two diode threshold voltage drops (2 V
t
). Accordingly, various improvements have been made to improve charge pump performance as shown for example in U.S. Pat. No. 6,294,948, the disclosure of which is incorporated herein by reference. Circuitry has been developed to bring output voltage up to two times Vcc or higher. It is also known to mutually connect the outputs of two single-phase charge pump circuits, operated out of phase with one another, to reduce ripple and achieve a more constant output voltage. Nonetheless, it is desirable to provide an improved charge pump circuit, and in particular a charge pump circuit which is more efficient than previous designs.
BRIEF SUMMARY OF THE INVENTION
The present invention includes a multiphase charge pump in which charge is shared between the respective driving sides of respective first and second bootstrap capacitors of a first phase circuit and a second phase circuit, to improve operating efficiency and lower current requirements.
According to the present invention, a charge pump is provided including a first phase circuit having a first bootstrap capacitor, a second phase circuit having a second bootstrap capacitor, and an equalization circuit adapted to transfer charge between the first bootstrap capacitor and the second bootstrap capacitor. The equalization circuit is operated according to a control signal such as a timing signal. The control signal causes a transfer of charge in a manner which reduces the requirement for input current supplied by an attached power supply, and also reduces waste current. In particular, when the driving side plate of the first capacitor is at ground potential, and the driving side plate of the second capacitor is at elevated potential, the equalization circuit is switched between the two driving sides prior to connection of the first (ground potential) capacitor to Vcc
12
and prior to connection of the second (elevated potential) capacitor to ground. In this manner, charge that would have been dumped to ground from the second capacitor, and wasted, is conducted to the first capacitor, which is due to be charged. The complementary operation occurs when the driving side of the second capacitor is at ground potential and the driving side of the first capacitor is at elevated potential. This reduces current sinking and power supply requirements, and improves charge pump efficiency.
These and other aspects and features of the invention will be more clearly understood from the following detailed description which is provided in conjunction with the accompanying drawings.
REFERENCES:
patent: 5493249 (1996-02-01), Manning
patent: 5642073 (1997-06-01), Manning
patent: 6008690 (1999-12-01), Takeshima et al.
patent: 6057725 (2000-05-01), Manning
patent: 6094095 (2000-07-01), Murray et al.
patent: 6097161 (2000-08-01), Takano et al.
patent: 6188590 (2001-02-01), Chang et al.
patent: 6255886 (2001-07-01), Manning
patent: 6272670 (2001-08-01), Van Myers et al.
patent: 6294948 (2001-09-01), Blodgett
patent: 6326834 (2001-12-01), Akita et al.
“Analog Very Large Scale Integrated Circuits Design of Two-Phase and Multi-phase Voltage Doublers with Frequency Regulation,” A Thesis presented to the Faculty of the College of Engineering and Technology, Ohio University, Nov., 1999.
Callahan Timothy P.
Dickstein , Shapiro, Morin & Oshinsky, LLP
Englund Terry L.
Micro)n Technology, Inc.
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