Miscellaneous active electrical nonlinear devices – circuits – and – Specific identifiable device – circuit – or system – With specific source of supply or bias voltage
Reexamination Certificate
1999-12-14
2001-08-14
Cunningham, Terry D. (Department: 2816)
Miscellaneous active electrical nonlinear devices, circuits, and
Specific identifiable device, circuit, or system
With specific source of supply or bias voltage
C327S534000
Reexamination Certificate
active
06275096
ABSTRACT:
FIELD OF THE INVENTION
This invention relates to integrated circuits and more specifically to a circuit and method for maintaining a supply voltage generated internally within an integrated circuit.
BACKGROUND OF THE INVENTION
It is often necessary to generate a supply voltage internally within an integrated circuit. Memory circuits, for example, may require the internal generation of a specialized supply voltage as a boosted wordline supply voltage (for example at 3.3V) or as a negative wordline low supply (for example at −0.5V). A charge pump is a device readily incorporated onto an integrated circuit which can be used to generate and maintain an internal supply voltage from an external voltage supply.
By way of illustration only and not intended to limit the meaning of “charge pump” to that particularly shown,
FIG. 9
shows a simple schematic for a charge pump
250
used to generate a supply voltage Vout from a first constant voltage input Vdd. The charge pump
250
receives a CLK input, which determines the charge transfer rate, and a control signal P
1
, which controls on-off switching of the charge pump. As will be understood, CLK provides the charge pump clock signal Vclk and its inverse /Vclk at which capacitors CP
2
and CP
1
are alternately held. During a first half cycle of CLK, Vclk is held high, /Vclk is held low and CP
1
is charged from the voltage input Vdd such that the voltage on CP
1
rises toward /Vclk+Vdd. During a second half cycle of CLK, Vclk falls low, while /Vclk is raised high. This causes the potential on CP
1
to rise, while the potential on CP
2
temporarily falls such that charge stored on CP
1
is transferred to CP
2
. Finally, during a second full cycle of CLK, charge is transferred from CP
2
onto the generated voltage supply output Vout.
Demand for current from a supply voltage varies depending on the operational state of the integrated circuit. For example, in many systems such as computers and printers, a memory chip is sometimes operated in an active mode in which relatively high current is required; for example, to access data on the chip, and at other times is operated in a standby mode or “sleep mode” in which relatively little current is required, such as is required to merely protect internal steady state voltage levels, e.g. Vbleq against leakage currents when no memory cells are accessed.
FIG. 10
shows an example of a prior art charge pump system having both active charge pumps
124
and a standby charge pump
126
. The active pumps
124
are enabled by a “pump enable” signal P
1
, while the standby charge pump
126
remains continuously enabled to supply current to the chip, such as is required to maintain the voltage level of the supply Vout against degradation from charge leakage. The active pumps
124
are designed to meet the large demands for current of active operation and therefore, have a higher pumping rate, i.e. have higher capacity or higher charge transfer rate, than the standby charge pump
126
. On the other hand, the standby charge pump
126
is designed to consume little power and to maintain the output voltage at a nearly constant level for long periods of time and thus is designed with a lower pumping rate, i.e. is slower.
The standby pump
126
is only needed to replenish the charge that leaks away during standby mode or sleep mode, when no wordlines are activated within the chip. At any time that a wordline is activated for access to a stored bit or for a refresh operation, the active pumps are switched on. The standby charge pump
126
operates continuously at a single and slower speed compared to the active pump; i.e., based on a CLK frequency that does not change. Heretofore, because the standby charge pump was continuously operated at lower output current than active charge pumps, the standby pump had to be designed as a separate unit dedicated to that function. However, although the standby charge pump
126
provides considerably less output current than an active charge pump
124
, the chip area required to implement the standby charge pump
126
is comparable to that required to implement the active charge pump
124
.
FIG. 11
is a timing diagram illustrating the operation of the prior art charge pump system shown in FIG.
10
. Active charge pumps
124
are conventionally driven by a ring oscillator that has a fixed output frequency which functions as a CLK input to the charge pump in a similar manner to the charge pump described above with reference to FIG.
9
. Consequently, in an “active interval” of operation, active charge pumps
124
cause the output voltage to rise and fall relatively quickly, because the active charge pumps
124
can only be activated or deactivated based on the output voltage Vout exceeding a single reference voltage Vref. The level of “ringing” depends on the limiter speed and the impedance of the wiring. A limiter with a slower feedback speed and high wiring resistance results in higher level of ringing. This is because when the limiter detects the output level below the target level, it will activate a control signal (not shown) to turn the pump on. First, it takes time to trigger the control signal, then it takes more time to communicate the control signal along the wiring back to the charge pump. During these times, the voltage level will continue to undershoot. Similarly, when the limiter detects the output level has reached the target level, it generates a control signal to shut off the charge pump. However, the delay in generating the control signal and communicating it back to the charge pump causes the voltage level to overshoot.
One way to reduce such ringing would be to utilize a high speed limiter. However, high speed limiters are generally considered unsuitable because of their high power consumption owing to the use of a resistive voltage divider and a differential amplifier which draw high DC current. Another possibility would be to decrease wiring impedance by using wider conductors. However, doing so would directly contribute to an increase in chip area. The relatively large “ringing” in the Vout voltage level introduces noise into the memory chip. The standby charge pump
126
also operates during the active interval, but its output current has little effect upon the rise and fall of Vout, its output current being much smaller than that of the active charge pumps
124
.
In a standby interval of operation, the active pumps
124
are switched off by the pump enable signal P
1
becoming disabled. However, the standby pump
126
is not disabled, but continues to operate when needed to restore the output voltage Vout to its target level. In this manner the output voltage Vout is maintained at or near its target level during both active and standby intervals.
It is an object of the present invention to provide a charge pump system in which the dedicated standby charge pump is eliminated, thereby reducing the layout area on the semiconductor chip.
It is another object of the invention to provide a charge pump system in which the rate of charge transfer to the voltage supply varies as a function of the voltage level reached by the voltage supply.
Still another object of the invention is to provide a charge pump system in which different groups of charge pumps are independently switched on and off in response to the voltage supply reaching different predetermined voltage levels.
Still another object of the invention is to more precisely control the voltage supply level by varying the rate of charge transfer thereto based on the voltage level reached, thereby reducing the amount of ringing and noise coupled onto the voltage supply line.
SUMMARY OF THE INVENTION
These and other objects of the invention are provided by the multiple charging rate charge pump system and method of the present invention.
The charge pump system operates such that when the level of the generated voltage supply is lower than a first predetermined level, first and second charge pump groups are operated to increase the voltage rapidly towards its target level. When the voltage exceed
Hsu Louis L. C.
Weinfurtner Oliver
Wordeman Matthew R.
C. Li Todd M.
Cunningham Terry D.
International Business Machines - Corporation
Neff Daryl K.
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