The present invention relates to the field of charge pump generators and more particularly to a method of controlling a charge pump generator and a related charge pump generator with reduced low-frequency noise.
Charge pump voltage generators are largely used in many integrated circuits (ICs) for supplying the ICs at a pre-established voltage VNEG that should remain constant as the current absorbed by the load varies. An example of a common charge pump voltage generator is shown in
The circuit of
In practice, this loop controls the duty cycle at a constant frequency when the charge current is above a certain threshold that depends upon the supply voltage, the on-resistances RON of the switches SW1 and SW2, the pump capacitance CP and the delay of the feedback line, constituted by the comparator and by the logic gates. TCK being the period of the clock signal CK, and Qmin being the minimum charge transferred from the pump capacitor CP to the tank capacitor CT, the load Iload must absorb a minimum current Imin given by the following equation:
to switch the switches SW1 and SW2 at each period of the clock signal CK.
If the current Iload is smaller than the value Imin, the charge transferred in a clock period from the capacitor CP to the capacitor CT is larger than that necessary for delivering this current for a clock period. The voltage VNEG does not reach the threshold VREF within the current period and the output of the AND gate remains null for more consecutive clock periods.
This situation is undesirable because it generates switching noise in frequency intervals that should be as free as possible from noise for a correct operation of circuits supplied by the charge pump. Indeed, the switches SW1 and SW2 generate switching noise centered around the frequency of the clock signal, when they switch at each period of the clock signal CK, and at a smaller and smaller frequency if they do not switch for more consecutive clock periods. This consequent low frequency noise may disturb sensitive operation of circuits supplied by the charge pump.
The published patent application US 2002/0105312 to Texas Instruments Inc. discloses a charge pump regulator with adjustable output current. In this device, the charging of the tank capacitor is regulated via switches with different on-resistances. A drawback of this approach is that the switches with low on-resistance occupy a relatively large silicon area.
This invention provides a method of controlling a charge pump generator and a relative charge pump generator with a reduced low frequency switching noise and a reduced silicon area consumption.
According to the method of this invention, the electric charge transferred in a charge transfer phase from the pump capacitor to the tank capacitor is diminished by reducing the amplitude of the voltage swing on the transfer capacitor proportionally to the current to be supplied. Preferably, this is done by limiting the maximum voltage on the pump capacitor to a certain value. This maximum value is calculated such to make the voltage on the transfer capacitor reach a certain minimum voltage at the end of the charge transfer phase.
The method of this invention is implemented in a charge pump generator having a driving circuit that isolates the pump capacitor when the voltage on it reaches the maximum value. In so doing, the above mentioned problems of low-frequency switching noise are overcome without realizing switches of very low on-resistance, that require a relatively large silicon area.
To center the noise generated by the switches SW1 and SW2 at the frequency of the clock signal CK, the switches are switched at each clock period. As a consequence, if the current Iload absorbed by the load supplied by the charge pump generator diminishes, it is necessary to also diminish the value Imin. This may be done only by reducing the minimum charge transferred from the pump capacitor CP to the tank capacitor CT proportionally to the current Iload absorbed by the circuit supplied by the charge pump, because the period TCK of the clock signal CK is generally fixed by design specifications.
VcpSTART being the voltage on the nodes of the pump capacitor at the instant in which the switches SW1 and SW2 are turned on, Tloop being the duration of the time interval in which the switches SW1 and SW2 are turned on in a clock period,
RON being the on resistance of the two identical switches SW1 and SW2.
The voltage VNEG, as the period TCK of the clock signal, is fixed by design specifications. The ratio
may hardly be modified with sufficient precision.
According to the method of this invention, the size of the two switches SW1 and SW2 need not be increased to reduce their on-resistance, as per the prior art approach. According to this invention, the voltage VcpSTART is reduced such to make the current Imin equal to the current Iload absorbed by the load. The charge Qmin transferred from the capacitor CP to the capacitor CT is
Qmin=QSTART−QEND (5)
QSTART and QEND being the charge on the pump capacitor CP at the beginning and at the end of the charge transfer phase. By imposing that the minimum current Imin be equal to the current absorbed by the load Iload, the following equation holds:
Considering that the charge on the pump capacitor is proportional to the voltage on it and that the proportionality factor is the capacitance, CP, the following equation may be written:
wherein VcpEND is the voltage on the pump capacitor at the end of the transfer charge phase. Equation (7), together with equation (3), allows a determination of the values of the maximum and minimum voltage on the capacitor CP as a function of the current absorbed by the load Iload and of the other parameters of the charge pump generator.
According to this invention, a control circuit for a charge pump generator for establishing a maximum voltage VcpSTART on the pump capacitor CP is depicted in
When the logic signal STOP is asserted, the switches SW3 and SW4 are turned off and the charging phase of the pump capacitor CP is stopped. By properly determining the voltage at the beginning of a new charge phase VcpSTART according to equation (3), the voltage on the capacitor CP is exactly VcpEND exactly when the regulated voltage surpasses the reference threshold VREF1.
An embodiment of a charge pump generator of this invention, that includes the control circuit of
Results of simulations of the operation of the charge pump generator of the invention depicted in
As soon as the regulated voltage becomes smaller than the threshold VREF1, set to −3V in the shown example, the comparator COMP of
When the clock signal CK switches low, a charge phase is started. The regulated voltage is always sustained only by the tank capacitor CT and thus its absolute value continues diminishing, while the switches SW3 and SW4 are closed and the pump capacitor CP charges. When the voltage VCP reaches the value VcpSTART, the control circuit of
With the charge pump capacitor of this invention, the switching noise generated by the switches SW1 and SW2 remains substantially confined around the clock frequency, where it may be easily filtered without limiting the performances of the circuits supplied by the charge pump and without using purposely made low on-resistance switches, that occupy a relatively large silicon area.
Number | Date | Country | Kind |
---|---|---|---|
VA2004A0029 | Jul 2004 | IT | national |
Number | Name | Date | Kind |
---|---|---|---|
6392904 | Bayer et al. | May 2002 | B1 |
6661683 | Botker et al. | Dec 2003 | B2 |
20020105312 | Knight | Aug 2002 | A1 |
20060001474 | Armaroli et al. | Jan 2006 | A1 |
Number | Date | Country | |
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20060017491 A1 | Jan 2006 | US |