The disclosed embodiments relate to electronic devices, and, in particular, to semiconductor devices with a charge recycling mechanism.
Electronic devices, such as semiconductor devices, memory chips, microprocessor chips, and imager chips, can include a charge pump (e.g., a DC to DC converter that functions as a power source) to create a voltage that is different (e.g., higher or lower) than the available source voltage (e.g., ‘Vdd’). Charge pumps can include components (e.g., diodes, switches, comparators, capacitors, resistors, or a combination thereof) that are organized to provide an output voltage that is boosted or reduced from an incoming source voltage.
Some charge pumps can include the components arranged in units or stages (e.g., such that the connections between or relative arrangements of the units can be reconfigured to adjust one or more capabilities of the charge pump).
The output voltage can be used to drive a load as illustrated in
The technology disclosed herein relates to electronic devices (e.g., semiconductor-level devices, sets of analog circuitry components, etc.), systems with electronic devices, and related methods for operating electronic devices in association with charge pumps and/or voltage booster mechanism (e.g., double boosted charge pumps) therein. The electronic devices can include in each stage a clock booster (e.g., a 2-phase NMOS clock doubler) for initially boosting an input voltage, a switching module for routing the initially boosted voltage, and a secondary booster for further boosting the input voltage using the initially boosted voltage. The electronic devices can operate the circuitry therein to recycle charges stored in the secondary booster and use it to precharge in the clock booster instead of discharging the charges to ground. The electronic devices can use a recycling duration to leave the secondary booster connected to the clock booster instead of isolating the circuits and connecting the secondary booster to ground for discharge. The charges stored in the secondary booster can flow into the clock booster and contribute to the precharging operation.
Each of the charging stages 202 (e.g., each a double boosted charge pump) can include a clock booster 204 (e.g., an output booster, such as a clock doubler), a secondary booster 206 (e.g., a higher voltage booster circuit, such as a Favrat booster), and a switching module 208 (e.g., a system or a set of switches and electrical connections). The clock booster 204 can be electrically coupled to the secondary booster 206 through the switching module 208. For example, a boosted intermediate voltage 210 (e.g., an intermediate voltage, such as ‘2Vdd’, that is greater than and/or boosted from a source input voltage, such as ‘Vdd’) from the clock booster 204 can be routed through the switching module 208 and provided as an input at the secondary booster 206. The secondary booster 206 can use the boosted intermediate voltage 210 from the clock booster 204 to further increase a previous stage input voltage 212 (e.g., ‘Vdd’ for the first stage or a stage output voltage 214 from a preceding secondary booster for subsequent stages). The stage output voltage 214 resulting from boosting the stage input voltage can be provided as an input voltage to the subsequent stage (e.g., as the stage input to subsequent instance of the secondary booster or as an output to the load).
In some embodiments, the switching module 208 can include multiple switching paths including one or more switches (e.g., parallel paths each including one or more NMOS transistor), one or more complementary switches (e.g., one or more PMOS transistors), or a combination thereof. For example, the switching module 208 can include a first PMOS transistor 222 connected to the clock booster 204 on one end and a first NMOS transistor 224, the secondary booster 206, or a combination thereof on an opposing end. The switching module 208 can further include a second PMOS transistor 226 connected to the clock booster 204 on one end and a second NMOS transistor 228, the secondary booster 206, or a combination thereof on an opposing end.
The charging stages 202 including the clock booster 204 and the switching module 208 (e.g., for providing a voltage greater than the input voltage, such as ‘2Vdd’) with the secondary booster 206 to provide increased charging efficiency. In comparison to the traditional switch pumps, the charge pump illustrated in
In some embodiments, the clock doubler 302 can include a doubler capacitor 322 connected to a source switch 324 on one node and a doubler charging switch 326 on an opposite node. Opposite the doubler capacitor 322, the source switch 324 can be connected to a power source (e.g., for accessing an input voltage 386, represented as ‘Vdd’) and the doubler charging switch 326 can be connected to a periodic signal used to generate the boosted intermediate voltage 210 of
In some embodiments, the switching module 306 can include a connecting switch 342 for controlling an electrical connection between the clock doubler 302 and the secondary booster 304. When closed or turned on, the connecting switch 342 can connect the clock doubler 302 and the secondary booster 304 to provide the boosted output to the secondary booster 304. When open or turned off, the connecting switch 342 can electrically isolate the clock doubler 302 and the secondary booster 304.
The switching module 306 can further include a discharging switch 344 between the connecting switch 342 and the secondary booster 304 configured to discharge energy from the secondary booster 304 to ground. The discharging switch 344 can generally operate in a complementary manner to the connecting switch 342. For example, for the discharging operation, the discharging switch 344 (e.g., based on closing or turning on) can connect the secondary booster 304 to ground when the connecting switch 342 (e.g., based on opening or turning off) isolates the clock doubler 302 from the secondary booster 304. For the charging or boosting operation, the discharging switch 344 (e.g., based on opening or turning off) can isolate the secondary booster from ground when the connecting switch 342 (e.g., based on closing or turning on) connects the clock doubler 302 and the secondary booster 304.
Additionally, for discharging the secondary booster 304, the switching module 306 can operate to recycle at least part of the energy in the secondary booster 304 and send it to the clock doubler 302 instead of discharging all of the remaining charges to a lower potential node (e.g., electrical ground). The clock doubler 302 can use the remaining charges to precharge the doubler capacitor 322, which can improve overall efficiency based on reducing a charging duration required to charge the doubler capacitor 322 and/or demand on the power source (e.g., based on going from a positive voltage level to Vdd instead of from zero volts). To recycle the charges, the connecting switch 342 can remain closed/on and the discharging switch 344 can remain open/off for a portion of the discharging operation.
The recycling process can utilize the remaining charges from a booster capacitor 362 in the secondary booster 304. The secondary booster 304 can use the booster capacitor 362 with an input switch 364 and an output switch 366 to further boost the boosted intermediate voltage 210 and/or the input voltage 386 during a charging operation (e.g., based on a rising edge of the periodic signal controlling the charging operation). For the discharging operation (e.g., based on a falling edge of the periodic signal), the charges stored on the booster capacitor 362 can be discharged or removed as discussed above.
For the recycling process, the charges from the booster capacitor 362 can contribute to or increase a precharging voltage 382 (e.g., represented as ‘Vprecharge’) at the doubler capacitor 322. Separately, the booster capacitor 362 can have an intermediate node voltage 384 (e.g., represented as ‘Vx’) at a port or a node connected to the connecting switch 342. When the connecting switch 342 is closed (e.g., when the doubler capacitor 322 is discharged or at a lower potential than the intermediate node voltage 384), recycled charge 390 can go from the booster capacitor 362 to the doubler capacitor 322 (e.g., with the intermediate node voltage 384 matching the precharging voltage 382 (Vx=Vprecharge) as a result). The intermediate node voltage 384 can decrease (e.g., by an amount corresponding to the recycled charge 390) based on a capacitance level of the doubler capacitor 322, the booster capacitor 362, or a combination thereof.
After recycling, the connecting switch 342 can open to isolate the clock doubler 302 from the secondary booster 304 (e.g., isolating the doubler capacitor 322 and the booster capacitor 362). The electronic device 300 can remove discharge loss 388 (e.g., charges that remain on the booster capacitor 362 after the recycling process) from the booster capacitor 362 based on closing the discharging switch 344.
Also after the recycling, the electronic device 300 can further increase the precharging voltage 382 using source-charging energy 392 from the input source to the doubler capacitor 322. The electronic device 300 can increase the precharging voltage 382 based on closing the source switch 324 and connecting the doubler capacitor 322 to the input voltage 386.
The slave-booster 406 can include a driver switch 422 (e.g., similar to the source switch 324 but for the charging/driving operation instead of the control operations) connected to a driver capacitor 424 (e.g., similar to the doubler capacitor 322 but for the charging/driving operation instead of the control operations). For example, a gate of the driver switch 422 can be connected to one of the controller switches 412 and/or one of the controller capacitors 416. The driver capacitor 424 can be controlled based on clock signals 432 (e.g., represented as ‘CLK’ (not shown) or ‘!CLK’ that represents an opposite or a complementary signal of ‘CLK’). The driver capacitor 424 can further have greater capacitance than the controller capacitors 416 (e.g., based on a factor of 10 or more, such as for controlling based on the controller capacitors 416 and for driving the load based on the driver capacitor 424).
The slave-booster 406 can be connected to the secondary booster 304 through the switching module 306 of
The switching module 306 can further include a module second switch 428 (e.g., the discharging switch 344 of
The switching module 306 can operate the switches based on a module first signal 436, a module second signal 438, or a combination thereof. The module first signal 436 can operate the module first switch 426 and the module second signal 438 can operate the module second switch 428. For example, the module first signal 436 can connect the module first switch 426 (e.g., based on turn the switch on) for a charging/driving process (e.g., rising edge of one or more of the clock master signals 434 and/or the clock signals 432) and for the recycling process. The module second signal 438 can connect the module second switch 428 for a discharging process (e.g., after the recycling process).
For illustrative purposes, the electronic device is shown in
Also for illustrative purposes, non-ideal losses to ground (e.g., corresponding to capacitor implementations, such as residual substrate capacitances for CMOS implementations) for the boosting and/or clock-doubler capacitors have been shown as dotted lines representing capacitances to ground. The charge recycling operations discussed herein can compensate for the non-ideal losses in the clock-doubler capacitors and/or the secondary booster capacitors.
The timing for input signals can be based on a recycling duration 502 (e.g., a duration for recycling the source-charging energy 392 and/or the recycled charge 390 from the booster capacitor 362 of
The input signals can keep or operate the connecting switch 342 of
Also during the recycling duration 502, the module first signal 436 can be low (e.g., for PMOS, a negative pulse with a pulse width equal to the recycling duration 502) for connecting the module first switch 426 and discharging the intermediate node voltage 384 from the booster capacitor 362 to the driver capacitor 424. As such, the intermediate node voltage 384 can be reduced according to the recycled charge 390 and/or the source-charging energy 392 (e.g. from 2Vdd to Vdd).
After the recycling duration, the clock signals 432, the clock master signals 434, or a combination thereof can resume the periodic portions for operating/precharging the clock booster 402 of
Recycling the recycled charge 390 from the booster capacitor 362 to the doubler capacitor 322 through the connecting switch 342 provides increased efficiency for charging capacitors. Based on the recycling, the device can begin charging the doubler capacitor 322 having the recycled charge 390 thereon instead of charging from zero voltage. Accordingly, recycling the recycled charge 390 instead of discharging to ground as the discharge loss 388 can reduce the source-charging energy 392 in comparison to charging from zero voltage.
At block 602, the electronic device (e.g., a charge pump, such as a double-boosted charge pump) can initiate (e.g., using the clock booster 204 of
The electronic device can precharge based on charging signals (e.g., the clock signals 432 of
In some embodiments, the electronic device can precharge using the clock master signals 434 (e.g., CLK_MSTR and/or !CLK_MSTR). For example, the electronic device (e.g., for double-boosted charge pumps including master-slave configuration) can include the master-controller 404 of
At block 604, the electronic device can generate an output (e.g., the stage output voltage 214 of
At block 606, the electronic device can recycle charges from the second capacitor to charge the first capacitor. For example, after generating the output (e.g., charging the booster capacitor 362), the electronic device can recycle charges (e.g., during the recycling duration 502, during or prior to a falling edge and/or a lower portion of one or more charging signals, or a combination thereof) from the booster capacitor 362 to charge the doubler capacitor 322, the driver capacitor 424, or a combination thereof.
For recycling, at block 662, the electronic device can set, control, and/or drive the charging signals (e.g., the clock signals 432, the clock master signals 434, a portion or a segment thereof, or a combination thereof). For example, the electronic device (e.g., using a controlling circuit, a state machine, other circuits within the device, etc.) can set the clock signals 432 low (e.g., for preventing or delaying the precharging operation). The electronic device can set the clock signals 432 based on delaying a rising portion of the clock signals 432 (e.g., the CLK signal) after the corresponding complementary signals (e.g., the !CLK signal) goes low. The electronic device can use the clock signals 432 that are complementary, but not overlapping each other (e.g., during the recycling duration 502, which can occur every half cycle of the clock signals 432 where one of the clock signals 432 is low, the other of the clock signals 432 can also remain low).
In some embodiments, the electronic device can maintain the states or levels of the clock master signals 434 during the recycling duration 502. For example, as illustrated in
Also for recycling, at block 664, the electronic device can operate switches for the switching module 208 and/or the switching module 306. The electronic device can operate the connecting switch 342, the module first switch 426, the discharging switch 344, the module second switch 428, or a combination thereof during the recycling duration 502 for the recycling operation. For example, the electronic device can control or set the module first signal 436 of
Based on the charging signals and the switch operations, the recycled charge 390 can transfer or flow from the booster capacitor 362 to the doubler capacitor 322/the driver capacitor 424 through the connecting switch 342/the module first switch 426 during the recycling duration 502. Accordingly, the discharging/recycling of the recycled charge 390 can reduce the intermediate node voltage 384 of
At block 608, the electronic device can discharge the second capacitor and removed the charges remaining after the recycling duration 502. At the end of the recycling duration 502, the electronic device can operate the switches, control the charging signals, or a combination thereof to discharge the intermediate node voltage 384 remaining after discharging/recycling the recycled charge 390.
At block 682, the electronic device can open or disconnect the connecting switch 342/the module first switch 426 at the end of the recycling duration 502 for the discharging operation. For example, the electronic device can set or control the module first signal 436 or a corresponding signal to open or disconnect the connecting switch 342/the module first switch 426, thereby isolating the second capacitor from the first capacitor.
At block 684, the electronic device can close or connect the discharging switch 344/the module second switch 428 for the discharging operation. For example, at the end of the recycling duration 502 and/or after or contemporaneous with block 682, the electronic device can set or control the module second signal 438 or a corresponding signal to close or connect the discharging switch 344/the module second switch 428, thereby connecting the second capacitor to the electrical ground or the lower voltage level.
At block 686, the electronic device can control or set the charging signals. For example, the electronic device can set or drive one of the clock signals 432 (e.g., the signal complementary to the one that went low immediately before the recycling duration 502) low after or at the end of the recycling duration 502. Also for example, the electronic device can set or drive the clock master signals 434 to change states (e.g., transitioning from high to low or from low to high) after or at the end of the recycling duration 502.
The electronic device can discharge the intermediate node voltage 384 at the booster capacitor 362 (e.g., charges remaining after discharging/recycling the recycled charge 390) based on the charging signals and/or the switch settings. Further, the electronic device can begin the precharging process for charging the first capacitor after the recycling duration 502. Accordingly, the precharging process can charge the first capacitor having the recycled charge 390 thereon instead of from zero volt potential. As a result, the recycling operation can increase the efficiency of the overall charging operation by decreasing the source-charging energy 392 of
At block 702, circuit for the charge pump (e.g., the electronic device 200 of
At block 722, providing the circuit can further include providing switches, such as the connecting switch 342 of
At block 704, the circuit can be configured for signal timings. For example, the circuit can be connected or manufactured (e.g., based on silicon-level processing or connecting circuit components) to implement the signal timings (e.g., as illustrated in
At block 742, configuring the circuit can include configuring the charging signals. For example, the state machine or the controller circuit can be configured or the firmware/software can be loaded for controlling the clock signals 432 of
At block 744, configuring the circuit can include configuring the switch timing. For example, the state machine or the controller circuit can be configured or the firmware/software can be loaded for controlling the module first signal 436 of
From the foregoing, it will be appreciated that specific embodiments of the present technology have been described herein for purposes of illustration, but that various modifications may be made without deviating from the disclosure. In addition, certain aspects of the disclosure described in the context of particular embodiments may be combined or eliminated in other embodiments. Further, while advantages associated with certain embodiments have been described in the context of those embodiments, other embodiments may also exhibit such advantages. Not all embodiments need necessarily exhibit such advantages to fall within the scope of the present disclosure. Accordingly, the disclosure and associated technology can encompass other embodiments not expressly shown or described herein.
This application is a continuation of U.S. patent application Ser. No. 15/849,098, filed Dec. 20, 2017, which is incorporated herein by reference in its entirety. This application contains subject matter related to an U.S. Patent Application by Michele Piccardi titled “ELECTRONIC DEVICE WITH AN OUTPUT VOLTAGE BOOSTER MECHANISM.” The related application is assigned to Micron Technology, Inc., and is identified as U.S. patent application Ser. No. 15/849,052, filed Dec. 20, 2017, now issued as U.S. Pat. No. 10,211,724. The subject matter thereof is incorporated herein by reference thereto. This application contains subject matter related to an U.S. Patent Application by Michele Piccardi titled “ELECTRONIC DEVICE WITH A CHARGING MECHANISM.” The related application is assigned to Micron Technology, Inc., and is identified as U.S. patent application Ser. No. 15/849,137, filed Dec. 20, 2017. The subject matter thereof is incorporated herein by reference thereto.
Number | Name | Date | Kind |
---|---|---|---|
4311923 | Luescher et al. | Jan 1982 | A |
5043858 | Watanabe | Aug 1991 | A |
5381051 | Morton | Jan 1995 | A |
5493486 | Connell et al. | Feb 1996 | A |
5818289 | Chevallier et al. | Oct 1998 | A |
5936459 | Hamamoto | Aug 1999 | A |
6008690 | Takeshima | Dec 1999 | A |
6046626 | Saeki et al. | Apr 2000 | A |
6154088 | Chevallier | Nov 2000 | A |
6359798 | Han | Mar 2002 | B1 |
6545529 | Kim | Apr 2003 | B2 |
6806761 | Aude | Oct 2004 | B1 |
7116154 | Guo | Oct 2006 | B2 |
7239193 | Fukuda | Jul 2007 | B2 |
7439793 | Lee | Oct 2008 | B2 |
7576523 | Ogawa et al. | Aug 2009 | B2 |
7602233 | Pietri et al. | Oct 2009 | B2 |
7652522 | Racape | Jan 2010 | B2 |
7994844 | Chen et al. | Aug 2011 | B2 |
8026755 | Ni et al. | Sep 2011 | B2 |
9502972 | Michal et al. | Nov 2016 | B1 |
9787176 | Dong | Oct 2017 | B2 |
9793794 | Stauth et al. | Oct 2017 | B2 |
10211724 | Piccardi | Feb 2019 | B1 |
10211725 | Piccardi | Feb 2019 | B1 |
10312803 | Piccardi | Jun 2019 | B1 |
20060290411 | Smith et al. | Dec 2006 | A1 |
20070035973 | Kitazaki et al. | Feb 2007 | A1 |
20080012627 | Kato | Jan 2008 | A1 |
20080122506 | Racape | May 2008 | A1 |
20090108915 | Liao | Apr 2009 | A1 |
20090121780 | Chen et al. | May 2009 | A1 |
20090174441 | Gebara et al. | Jul 2009 | A1 |
20130113546 | Shay et al. | May 2013 | A1 |
20130222050 | Siao | Aug 2013 | A1 |
20150015323 | Rahman et al. | Jan 2015 | A1 |
20160268893 | Dong et al. | Sep 2016 | A1 |
20170317584 | Tanikawa | Nov 2017 | A1 |
20180191243 | Shay et al. | Jul 2018 | A1 |
Entry |
---|
Favrat, P. et al., “A New High Efficiency CMOS Voltage Doubler”, Proceedings of the IEEE 1997 Custom Integrated Circuits Conference, (1997), p. 259-262. |
U.S. Appl. No. 15/849,137—Unpublished patent application by Michele Piccardi, titled “Electronic Device With a Charging Mechanism”, filed Dec. 20, 2017, 32 pages. |
Number | Date | Country | |
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20190273432 A1 | Sep 2019 | US |
Number | Date | Country | |
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Parent | 15849098 | Dec 2017 | US |
Child | 16416699 | US |