US20010020839A1 - Voltage boosting device, in particular for speeding power-up of multilevel nonvolatile memories - Google Patents
Voltage boosting device, in particular for speeding power-up of multilevel nonvolatile memories Download PDFInfo
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- US20010020839A1 US20010020839A1 US09/778,330 US77833001A US2001020839A1 US 20010020839 A1 US20010020839 A1 US 20010020839A1 US 77833001 A US77833001 A US 77833001A US 2001020839 A1 US2001020839 A1 US 2001020839A1
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02M—APPARATUS FOR CONVERSION BETWEEN AC AND AC, BETWEEN AC AND DC, OR BETWEEN DC AND DC, AND FOR USE WITH MAINS OR SIMILAR POWER SUPPLY SYSTEMS; CONVERSION OF DC OR AC INPUT POWER INTO SURGE OUTPUT POWER; CONTROL OR REGULATION THEREOF
- H02M3/00—Conversion of dc power input into dc power output
- H02M3/02—Conversion of dc power input into dc power output without intermediate conversion into ac
- H02M3/04—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters
- H02M3/06—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using resistors or capacitors, e.g. potential divider
- H02M3/07—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using resistors or capacitors, e.g. potential divider using capacitors charged and discharged alternately by semiconductor devices with control electrode, e.g. charge pumps
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- the present invention refers to a voltage boosting device, and in particular for increasing the speed of power-up of multilevel nonvolatile memories.
- a first charge pump with low consumption and low performance
- a second charge pump with high performance, intervenes only when the memory is in the active state.
- the low consumption pump has the purpose of compensating the discharging of the high voltage nodes that is due to inevitable leakage currents during the standby state. Since these leakage currents are normally somewhat contained, the low consumption pump, albeit having a low level of performance, is sufficient for the purpose.
- the disclosed embodiment of the present invention provides a device for raising the voltage which, in a nonvolatile memory, allows a read voltage to rapidly reach a nominal value, in particular where at power-up the memory is set in standby.
- a voltage boosting device including a voltage regulator and a charge pump having an output terminal supplying a read voltage at a nominal value, the voltage regulator having a regulation terminal connected to the output terminal and a control output supplying a control voltage that has a first control level when the read voltage is lower than a preset value; the recharge pump having an enable terminal and an output connected to the output terminal; and an enable circuit having a first input connected to the control output, a second input receiving a power-up signal, and a pump enable output connected to the enable terminal of the charge pump and supplying a pump enable signal, the pump enable signal being set at a first logic level for activating the charge pump at least upon receiving the power-up signal.
- the enable circuit includes a memory circuit having an input connected to the second input of the enable circuit and an output supplying a power-up memory signal switching to a first level upon receiving the power-up signal; and an activation circuit having inputs connected to the control output and to the first node, and an activation mode connected to the pump enable terminal for supplying the pump enable signal in the presence of the first level of a bistable reset signal and as long as the control voltage has the first control value.
- the enable circuit includes a memory circuit having an input connected to the second input of the enable circuit, and an output supplying a power-up memory signal switching to a first level upon receiving the power-up signal and also including a sync stage having a first input, a second input, and a sink output, the first input and the second input of the sink stage connected, respectively, to the output of the memory circuit and to a chip enable terminal supplying a chip enable signal, and the sync output supplying a power-up sync signal having a pulse when the read voltage reaches the nominal value and the chip enable signal is set at an active value.
- FIG. 1 shows a block diagram of a voltage boosting device according to the present invention
- FIG. 2 shows a simplified circuit diagram of a first block of the device of FIG. 1;
- FIG. 3 shows a simplified circuit diagram of a second block of the device of FIG. 1;
- FIG. 4 shows the plots of selected electrical quantities taken on the diagram of FIG. 1.
- a memory 1 that includes a memory array 2 comprising a plurality of memory cells 6 arranged in rows and columns.
- the memory cells 6 belonging to a same row have their respective gate terminals connected to a word line 7 .
- a row decoder 8 selectively connects one of the word lines 7 of the memory array 2 with an output terminal 10 of the voltage boosting device 3 .
- the voltage boosting device 3 comprises a voltage regulator 11 , an enabling circuit 12 , a read charge pump 13 , and a standby charge pump 14 .
- the read charge pump 13 is of high performance and high consumption type, and is activated only at power-up and during active operation of the memory 1 ;
- the standby charge pump 14 is of low consumption and low performance type, and is kept in continuous operation, even in the standby condition.
- the voltage regulator 11 has a regulation terminal connected to the output terminal 10 and an input connected to a chip enable terminal 15 of the memory 1 , on which a chip enable signal CE is present, which is generated by a control unit of known type, which is not shown.
- an output 16 of the voltage regulator 11 is connected to the enable circuit 12 and supplies a control voltage V L .
- the enable circuit 12 which will be illustrated in detail hereinafter, has an input connected to the chip enable terminal 15 , from which it receives the chip enable signal CE, and a reset terminal 19 , which receives a power-up signal POR generated by a reset circuit in itself known, which is not shown in the figures. Furthermore, the enable circuit 12 has a pump enable output 17 supplying a pump enable signal PE, and a sync output 18 supplying a power-up sync signal ATDS.
- the read charge pump 13 has an enable terminal connected to the pump enable output 17 , and an output connected to the output terminal 10 of the voltage boosting device 3 and supplying a read voltage V R .
- the read voltage V R on the output terminal 10 is lower than a nominal value (FIG. 4).
- the control voltage V L supplied by the voltage regulator 11 is at a first control value, at which the enable circuit, as will be described in detail in what follows, brings the pump enable signal PE to a first logic level, for example a high logic level, thus activating the read charge pump 13 .
- the read voltage V R thus starts increasing until it reaches the nominal value, around which it is subsequently maintained by the voltage regulator 11 (FIG. 4).
- the control voltage V L supplied by the voltage regulator 11 decreases, remaining around a second control value (FIG. 4).
- the memory 1 is set in standby, and the enable circuit 12 brings the pump enable signal PE to a second logic level, for example a low logic level, so that the read charge pump 13 is deactivated.
- the standby charge pump 14 remains, instead, active.
- the enable circuit 12 at the moment in which the read voltage V R reaches the nominal value, causes the power-up sync signal ATDS to present a pulse (FIG. 4), as will be clarified later, and, moreover, supplies the first logic level of the pump enable signal PE, and thus maintains the read charge pump 13 in operation.
- the voltage regulator 11 can be made as will now be briefly described to enable a better understanding, with reference to FIG. 2.
- the voltage regulator 11 comprises a reference cell 20 , a resistive branch 21 , a driving inverter 22 , and a regulation transistor 23 .
- the reference cell 20 has its gate terminal connected to the output terminal 10 of the voltage boosting device 3 , its source terminal grounded, and its drain terminal connected to the resistive branch 21 .
- the reference cell 20 has a threshold voltage whereby it starts conducting current when the read voltage V R on the output terminal 10 exceeds the nominal value.
- the resistive branch 21 comprises a resistive transistor 25 , of implanted NMOS type, having its source terminal connected to the output 16 of the voltage regulator 11 , its drain terminal and gate terminal connected together and, via a PMOS interrupt transistor 27 , to a supply line 28 supplying a voltage V CC .
- the gate terminal of the interrupt transistor 27 receives a regulator enable signal RE generated by a regulator enable circuit 29 —which is per se known and not shown in detail—connected to the chip enable terminal 15 .
- the regulator enable signal RE has a low logic level, corresponding to a voltage value of approximately 0 V, and, after the read voltage V R has reached the nominal value, this value is equal to the chip enable signal CE.
- a first biasing transistor 30 and a second biasing transistor 31 are connected in series between the output 16 of the voltage regulator 11 and the drain terminal of the reference cell 20 .
- the first biasing transistor 30 has its source terminal and gate terminal connected together via an inverter 34
- the second biasing transistor 31 has its gate terminal connected to the supply line 28 .
- the driving inverter 22 connects the output 16 of the voltage regulator 11 to the gate terminal of the regulation transistor 23 , which moreover has its drain terminal and source terminal connected, respectively, to the output terminal 10 and to ground.
- the regulator enable signal RE is brought to a low level and turns on the interrupt transistor 27 .
- the reference cell 20 is inhibited, and the resistive branch 21 does not conduct current. Consequently, the control voltage V L on the output 16 of the voltage regulator 11 is at a value given by the following expression:
- V L V CC ⁇ V TN (1)
- V TN is the threshold voltage of the resistive transistor 25 , having a value of, for examples 1 V.
- Expression (1) moreover defines the first control value of the control voltage V L . In the presence of this first control value, the driving inverter 22 keeps the regulation transistor 23 off.
- FIG. 3 is a detailed diagram of the enable circuit 12 , which comprises an enable stage 35 and a sync stage 36 .
- an NMOS power-up transistor 37 has its source terminal and drain terminal connected, respectively, to ground and to a first node 39 , and its gate terminal connected to the reset terminal 19 .
- a first confirm inverter 40 and a second confirm inverter 41 which are connected together back-to-back, are coupled between the first node 39 and a second node 42 .
- a chain of delay transistors 45 connects the second node 42 to a gate terminal of an activation transistor 46 .
- the activation transistor 46 moreover has its source terminal grounded and its drain terminal connected to an activation node 47 .
- a PMOS natural transistor 48 has its drain terminal connected to the activation node 47 , its source terminal connected to the supply line 28 , and its gate terminal connected to the output 16 of the voltage regulator 11 . Since during the fabrication process the natural transistor 48 has not undergone implantation for threshold modification, it has a natural threshold voltage V TP higher than that of standard transistors and, in particular, higher than the threshold voltage V TN of the resistive transistor 25 (FIG. 2). For example, the natural threshold voltage V TP is 1.5 V.
- the activation transistor 46 and the natural transistor 48 make up an activation branch for the read charge pump 13 .
- An output inverter 50 is arranged between the activation node 47 and the pump enable output 17 of the enable circuit 12 , and supplies the pump enable signal PE.
- a reset circuit 51 connected between the pump enable output 17 and the second node 42 , comprises a reset inverter 52 and a reset transistor 53 .
- the reset inverter 52 is arranged between the pump enable output 17 and a gate terminal of the reset transistor 53 , which moreover has its source terminal grounded and its drain terminal connected to the second node 42 .
- a PMOS confirm transistor 54 is connected between the supply line 28 and the activation node 47 , and has its gate terminal connected to the gate terminal of the activation transistor 46 .
- the sync circuit 36 comprises a pair of inverters 56 which allow TTL-CMOS level adaptation, are arranged in series together, and connect the chip enable terminal 15 of the memory 1 to an excitation node 57 through a transfer gate 58 .
- a monostable circuit 60 has a first input connected to the excitation node 57 directly, and a second input also connected to the excitation node 57 , but through a phase inverter 61 , and an output forming the sync output 18 and supplying the power-up sync signal ATDS.
- An input inverter 62 is arranged between the first node 39 of the enable stage 35 and a control node 63 connected directly to a first control terminal 58 a of the transfer gate 58 and, through a control inverter 64 , to a second control terminal 58 b .
- a control signal SW is present on the control terminal 63 and brings the transfer gate 58 alternately into a conduction state or an inhibition state.
- the transfer gate 58 is brought into the conduction state when the control signal SW is at the low logic level, and into the inhibition state when the control signal SW is at the high logic level.
- the second control terminal 58 b is connected to the gate terminal of a second PMOS confirm transistor 65 , which has its source terminal connected to the supply line 28 and its drain terminal connected to the excitation node 57 .
- the power-up signal POR has a pulse (high logic level) when the supply voltage V CC is below a preset threshold, and, consequently, at power-up of the memory 1 , on the gate terminal of the power-up transistor 37 a high logic level is present, which corresponds to a voltage value approximately equal to that of the supply voltage V CC . Consequently, the power-up transistor 37 is on, and the first node 39 is low.
- the first confirm inverter 40 and second confirm inverter 41 force the low logic level (close to ground) on the first node 39 and the high logic level on the second node 42 , the high logic level propagating, through the chain of delay inverters 45 , as far as the gate terminal of the activation transistor 46 , thus turning this transistor on.
- the natural transistor 48 is, instead, initially off. As shown previously, in fact, the control voltage V L is at the first, higher, control voltage, given by Equation (1), and consequently the natural transistor 48 has a gate-to-source voltage lower than the natural threshold voltage V TP , and is inhibited.
- the activation node 47 is thus at the low logic level, while the first (high) logic level of the pump enable signal PE is on the pump enable output 17 , because of the presence of the output inverter 50 , and determines activation of the read charge pump 13 , as described previously with reference to FIG. 1.
- control signal SW is at the high logic level, owing to the presence of the input inverter 62 , and brings the transfer gate 58 in the inhibition state, preventing transmission of the chip enable signal CE.
- the second confirm transistor 65 which receives the low logic level on its gate terminal, and hence is on, maintains the excitation node 57 at the high logic level and inhibits generation of pulses by the monostable circuit 60 .
- the control voltage V L decreases, as described previously, and reaches the second control value, so turning on the natural transistor 48 .
- the natural transistor 48 is sized so as to be more conductive than the activation transistor 46 , the activation node 47 is brought to the high logic level, and hence the output inverter 50 switches, setting the pump enable signal PE at the second (low) logic level.
- the read charge pump 13 is thus deactivated, while the standby charge pump 14 (FIG. 1) is kept in operation to maintain the read voltage V R at the nominal value.
- the reset transistor 53 is turned on by the reset inverter 52 and brings the second node 42 to the low logic level. Consequently, the activation transistor 46 is inhibited, while the confirm transistor 54 starts conducting, so confirming the high logic level present on the activation node 47 .
- the reset transistor 37 , the first confirm inverter 40 and second confirm inverter 41 defines a bistable type memory circuit, which is set by the power-up signal POR and reset by the reset transistor 53 .
- the enable stage 35 remains in the condition that has been described until a read or write operation is requested. If, instead, the memory 1 is immediately set in the active state and hence the chip enable signal CE has an active value, the control voltage V L supplied by the voltage regulator 11 oscillates between the first control value and the second control value according to whether the read voltage V R is lower than or equal to the nominal value, as described above with reference to FIGS. 1 and 2. Consequently, the read charge pump 13 is alternately activated and deactivated by the pump enable signal PE, so maintaining the read voltage V R close to the nominal value.
- the pump enable signal PE determines activation of the read charge pump 13 at powering up of the memory 1 and during reading.
- the chip enable signal CE can thus be brought to the excitation node 57 and to the inputs of the monostable circuit 60 .
- the chip enable signal CE is at the non-active (high) value, which is equal to the logic level already present on the excitation node 57 before switching of the input inverter 62 . Consequently, the monostable circuit 60 is not excited and does not generate any pulse (the power-up sync signal ATDS remains low, and reading is not started).
- the chip enable signal CE is set at the active (low) level. Consequently, as soon as the read voltage V R reaches the nominal value, the control signal SW sets the transfer gate 58 in the conduction state and enables transfer of the active (low) level to the inputs of the monostable circuit 60 (the second confirm transistor 65 is inhibited, as explained above). The monostable circuit 60 is thus excited, and the power-up sync signal ATDS has a pulse of a preset duration, thus determining reading.
- the voltage boosting device according to the present invention affords the advantages described in what follows.
- the use of the read charge pump 13 at power-up enables power-up to be speeded up considerably even when the memory 1 is initially set in standby.
- the read charge pump 13 has high performance and is able to charge the output terminal 10 much faster than the standby charge pump 14 .
- the overall consumption of the voltage boosting device is low, in that the read charge pump 13 is deactivated as soon as the read voltage V R reaches the nominal value.
- a further advantage is represented by the possibility of generating a power-up sync pulse as soon as the read voltage presents a sufficiently high value. In this way, it is possible to carry out read operations directly at power-up of the memory 1 , without waiting for further clock cycles.
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Abstract
Description
- The present invention refers to a voltage boosting device, and in particular for increasing the speed of power-up of multilevel nonvolatile memories.
- As is known, in order to correctly read multilevel nonvolatile memories, it is necessary to supply the memory cells to be read with high voltages, i.e., higher than the supply voltages normally available. For this purpose, voltage boosting devices are employed that use voltage boosters (charge pumps) that are able to raise the voltage above the supply voltage, together with regulator stages for stabilizing the read voltage at around the nominal values required.
- According to a very widespread design, a first charge pump, with low consumption and low performance, is kept in continuous operation, also in standby conditions, whereas a second charge pump, with high performance, intervenes only when the memory is in the active state. In practice, the low consumption pump has the purpose of compensating the discharging of the high voltage nodes that is due to inevitable leakage currents during the standby state. Since these leakage currents are normally somewhat contained, the low consumption pump, albeit having a low level of performance, is sufficient for the purpose.
- Since the read voltage at input of the memory in the active state is already at the desired value and it is not necessary to raise it any further, reading upon re-entry from the standby condition is rendered faster, and the memory is, as a whole, faster. In addition, since the pump used in standby absorbs a very low power, consumption of the memory is not significantly increased.
- Known devices, however, present a number of drawbacks. In fact, if at power-up it is not immediately necessary to carry out operations of memory programming or reading, the memory itself is set in standby. In this case, the high performance pump is deactivated, and the read voltage must be brought to the nominal value by means of the low consumption pump, which, however, is not able to supply high charge currents. Consequently, the time required for the memory to reach nominal operating conditions, such as to guarantee proper execution of the programming and, in particular, reading, is long.
- On the other hand, even when reading is requested immediately at power-up and the memory is set in the active state, the memory is not able to carry out the operations requested. In order to prevent errors, in fact, the read voltage must stabilize at around the nominal value; consequently, it is necessary to wait for a clock cycle for the generation of a sync signal (normally called ATD) which enables reading. Thus, the time required for accessing the content of the memory following the power-up phase is long and represents a limitation of the performance of the memory itself.
- The disclosed embodiment of the present invention provides a device for raising the voltage which, in a nonvolatile memory, allows a read voltage to rapidly reach a nominal value, in particular where at power-up the memory is set in standby.
- A voltage boosting device is provided, the device including a voltage regulator and a charge pump having an output terminal supplying a read voltage at a nominal value, the voltage regulator having a regulation terminal connected to the output terminal and a control output supplying a control voltage that has a first control level when the read voltage is lower than a preset value; the recharge pump having an enable terminal and an output connected to the output terminal; and an enable circuit having a first input connected to the control output, a second input receiving a power-up signal, and a pump enable output connected to the enable terminal of the charge pump and supplying a pump enable signal, the pump enable signal being set at a first logic level for activating the charge pump at least upon receiving the power-up signal.
- In accordance with another aspect of the invention, the enable circuit includes a memory circuit having an input connected to the second input of the enable circuit and an output supplying a power-up memory signal switching to a first level upon receiving the power-up signal; and an activation circuit having inputs connected to the control output and to the first node, and an activation mode connected to the pump enable terminal for supplying the pump enable signal in the presence of the first level of a bistable reset signal and as long as the control voltage has the first control value.
- In accordance with another aspect of the invention, the enable circuit includes a memory circuit having an input connected to the second input of the enable circuit, and an output supplying a power-up memory signal switching to a first level upon receiving the power-up signal and also including a sync stage having a first input, a second input, and a sink output, the first input and the second input of the sink stage connected, respectively, to the output of the memory circuit and to a chip enable terminal supplying a chip enable signal, and the sync output supplying a power-up sync signal having a pulse when the read voltage reaches the nominal value and the chip enable signal is set at an active value.
- For a better understanding of the invention, an embodiment thereof is now described, as a non-limiting example, with reference to the attached drawings, wherein:
- FIG. 1 shows a block diagram of a voltage boosting device according to the present invention;
- FIG. 2 shows a simplified circuit diagram of a first block of the device of FIG. 1;
- FIG. 3 shows a simplified circuit diagram of a second block of the device of FIG. 1; and
- FIG. 4 shows the plots of selected electrical quantities taken on the diagram of FIG. 1.
- Referring initially to FIG. 1, shown therein is a
memory 1 that includes amemory array 2 comprising a plurality of memory cells 6 arranged in rows and columns. In particular, the memory cells 6 belonging to a same row have their respective gate terminals connected to a word line 7. Arow decoder 8, of known type, selectively connects one of the word lines 7 of thememory array 2 with anoutput terminal 10 of thevoltage boosting device 3. - The
voltage boosting device 3 comprises avoltage regulator 11, an enablingcircuit 12, aread charge pump 13, and astandby charge pump 14. The readcharge pump 13 is of high performance and high consumption type, and is activated only at power-up and during active operation of thememory 1; thestandby charge pump 14 is of low consumption and low performance type, and is kept in continuous operation, even in the standby condition. - The
voltage regulator 11 has a regulation terminal connected to theoutput terminal 10 and an input connected to a chip enableterminal 15 of thememory 1, on which a chip enable signal CE is present, which is generated by a control unit of known type, which is not shown. In addition, anoutput 16 of thevoltage regulator 11 is connected to the enablecircuit 12 and supplies a control voltage VL. - The enable
circuit 12, which will be illustrated in detail hereinafter, has an input connected to the chip enableterminal 15, from which it receives the chip enable signal CE, and areset terminal 19, which receives a power-up signal POR generated by a reset circuit in itself known, which is not shown in the figures. Furthermore, the enablecircuit 12 has a pump enableoutput 17 supplying a pump enable signal PE, and async output 18 supplying a power-up sync signal ATDS. - The
read charge pump 13 has an enable terminal connected to the pump enableoutput 17, and an output connected to theoutput terminal 10 of thevoltage boosting device 3 and supplying a read voltage VR. - At power-up of the
memory 1, the read voltage VR on theoutput terminal 10 is lower than a nominal value (FIG. 4). In this condition, the control voltage VL supplied by thevoltage regulator 11 is at a first control value, at which the enable circuit, as will be described in detail in what follows, brings the pump enable signal PE to a first logic level, for example a high logic level, thus activating theread charge pump 13. The read voltage VR thus starts increasing until it reaches the nominal value, around which it is subsequently maintained by the voltage regulator 11 (FIG. 4). In addition, the control voltage VL supplied by thevoltage regulator 11 decreases, remaining around a second control value (FIG. 4). - In this situation, if, after the power-up phase the chip enable signal CE is at a non-active level (normally a high logic level), the
memory 1 is set in standby, and the enablecircuit 12 brings the pump enable signal PE to a second logic level, for example a low logic level, so that theread charge pump 13 is deactivated. Thestandby charge pump 14 remains, instead, active. If, on the other hand, reading is requested immediately, and hence the chip enable signal CE is at an active level (normally a low logic level), the enablecircuit 12, at the moment in which the read voltage VR reaches the nominal value, causes the power-up sync signal ATDS to present a pulse (FIG. 4), as will be clarified later, and, moreover, supplies the first logic level of the pump enable signal PE, and thus maintains theread charge pump 13 in operation. - The
voltage regulator 11 can be made as will now be briefly described to enable a better understanding, with reference to FIG. 2. - As shown in this figure, the
voltage regulator 11 comprises areference cell 20, aresistive branch 21, adriving inverter 22, and a regulation transistor 23. - The
reference cell 20 has its gate terminal connected to theoutput terminal 10 of thevoltage boosting device 3, its source terminal grounded, and its drain terminal connected to theresistive branch 21. In addition, thereference cell 20 has a threshold voltage whereby it starts conducting current when the read voltage VR on theoutput terminal 10 exceeds the nominal value. - The
resistive branch 21 comprises aresistive transistor 25, of implanted NMOS type, having its source terminal connected to theoutput 16 of thevoltage regulator 11, its drain terminal and gate terminal connected together and, via aPMOS interrupt transistor 27, to asupply line 28 supplying a voltage VCC. The gate terminal of theinterrupt transistor 27 receives a regulator enable signal RE generated by a regulator enablecircuit 29—which is per se known and not shown in detail—connected to the chip enableterminal 15. In particular, at power-up of thememory 1, the regulator enable signal RE has a low logic level, corresponding to a voltage value of approximately 0 V, and, after the read voltage VR has reached the nominal value, this value is equal to the chip enable signal CE. - A
first biasing transistor 30 and asecond biasing transistor 31 are connected in series between theoutput 16 of thevoltage regulator 11 and the drain terminal of thereference cell 20. In addition, thefirst biasing transistor 30 has its source terminal and gate terminal connected together via aninverter 34, while thesecond biasing transistor 31 has its gate terminal connected to thesupply line 28. - The
driving inverter 22 connects theoutput 16 of thevoltage regulator 11 to the gate terminal of the regulation transistor 23, which moreover has its drain terminal and source terminal connected, respectively, to theoutput terminal 10 and to ground. - At power-up of the
memory 1, the regulator enable signal RE is brought to a low level and turns on theinterrupt transistor 27. However, given that the read voltage VR is lower than the nominal voltage, thereference cell 20 is inhibited, and theresistive branch 21 does not conduct current. Consequently, the control voltage VL on theoutput 16 of thevoltage regulator 11 is at a value given by the following expression: - V L =V CC −V TN (1)
- where VTN is the threshold voltage of the
resistive transistor 25, having a value of, for examples 1 V. Expression (1) moreover defines the first control value of the control voltage VL. In the presence of this first control value, thedriving inverter 22 keeps the regulation transistor 23 off. - When the read voltage VR reaches the nominal value, the
reference cell 20 starts conducting, and, consequently, in the resistive branch 21 a current starts flowing which causes a decrease in the control voltage VL (approximately down to the second control value—FIG. 4) and causes switching of thedriving inverter 22. The regulation transistor 23 is thus turned on and enables discharging of theoutput terminal 10, so that the read voltage VR will not exceed the nominal value. - FIG. 3 is a detailed diagram of the enable
circuit 12, which comprises an enablestage 35 and async stage 36. - In the enable
stage 35, an NMOS power-up transistor 37 has its source terminal and drain terminal connected, respectively, to ground and to afirst node 39, and its gate terminal connected to thereset terminal 19. - A
first confirm inverter 40 and asecond confirm inverter 41, which are connected together back-to-back, are coupled between thefirst node 39 and asecond node 42. - A chain of delay transistors45 (two in the example) connects the
second node 42 to a gate terminal of anactivation transistor 46. Theactivation transistor 46 moreover has its source terminal grounded and its drain terminal connected to anactivation node 47. A PMOSnatural transistor 48 has its drain terminal connected to theactivation node 47, its source terminal connected to thesupply line 28, and its gate terminal connected to theoutput 16 of thevoltage regulator 11. Since during the fabrication process thenatural transistor 48 has not undergone implantation for threshold modification, it has a natural threshold voltage VTP higher than that of standard transistors and, in particular, higher than the threshold voltage VTN of the resistive transistor 25 (FIG. 2). For example, the natural threshold voltage VTP is 1.5 V. Theactivation transistor 46 and thenatural transistor 48 make up an activation branch for the readcharge pump 13. - An
output inverter 50 is arranged between theactivation node 47 and the pump enableoutput 17 of theenable circuit 12, and supplies the pump enable signal PE. - A
reset circuit 51, connected between the pump enableoutput 17 and thesecond node 42, comprises areset inverter 52 and areset transistor 53. In particular, thereset inverter 52 is arranged between the pump enableoutput 17 and a gate terminal of thereset transistor 53, which moreover has its source terminal grounded and its drain terminal connected to thesecond node 42. - A
PMOS confirm transistor 54 is connected between thesupply line 28 and theactivation node 47, and has its gate terminal connected to the gate terminal of theactivation transistor 46. - The
sync circuit 36 comprises a pair ofinverters 56 which allow TTL-CMOS level adaptation, are arranged in series together, and connect the chip enableterminal 15 of thememory 1 to anexcitation node 57 through atransfer gate 58. - A
monostable circuit 60 has a first input connected to theexcitation node 57 directly, and a second input also connected to theexcitation node 57, but through aphase inverter 61, and an output forming thesync output 18 and supplying the power-up sync signal ATDS. - An
input inverter 62 is arranged between thefirst node 39 of theenable stage 35 and acontrol node 63 connected directly to afirst control terminal 58 a of thetransfer gate 58 and, through acontrol inverter 64, to asecond control terminal 58 b. A control signal SW is present on thecontrol terminal 63 and brings thetransfer gate 58 alternately into a conduction state or an inhibition state. In particular, thetransfer gate 58 is brought into the conduction state when the control signal SW is at the low logic level, and into the inhibition state when the control signal SW is at the high logic level. - In addition, the
second control terminal 58 b is connected to the gate terminal of a secondPMOS confirm transistor 65, which has its source terminal connected to thesupply line 28 and its drain terminal connected to theexcitation node 57. - Operation of the
enable circuit 12 is the following. The power-up signal POR has a pulse (high logic level) when the supply voltage VCC is below a preset threshold, and, consequently, at power-up of thememory 1, on the gate terminal of the power-up transistor 37 a high logic level is present, which corresponds to a voltage value approximately equal to that of the supply voltage VCC. Consequently, the power-up transistor 37 is on, and thefirst node 39 is low. Thefirst confirm inverter 40 andsecond confirm inverter 41 force the low logic level (close to ground) on thefirst node 39 and the high logic level on thesecond node 42, the high logic level propagating, through the chain ofdelay inverters 45, as far as the gate terminal of theactivation transistor 46, thus turning this transistor on. - The
natural transistor 48 is, instead, initially off. As shown previously, in fact, the control voltage VL is at the first, higher, control voltage, given by Equation (1), and consequently thenatural transistor 48 has a gate-to-source voltage lower than the natural threshold voltage VTP, and is inhibited. - The
activation node 47 is thus at the low logic level, while the first (high) logic level of the pump enable signal PE is on the pump enableoutput 17, because of the presence of theoutput inverter 50, and determines activation of the readcharge pump 13, as described previously with reference to FIG. 1. - Furthermore, in the described condition, the control signal SW is at the high logic level, owing to the presence of the
input inverter 62, and brings thetransfer gate 58 in the inhibition state, preventing transmission of the chip enable signal CE. Thesecond confirm transistor 65, which receives the low logic level on its gate terminal, and hence is on, maintains theexcitation node 57 at the high logic level and inhibits generation of pulses by themonostable circuit 60. - When the read voltage VR reaches the nominal value, the control voltage VL decreases, as described previously, and reaches the second control value, so turning on the
natural transistor 48. Since thenatural transistor 48 is sized so as to be more conductive than theactivation transistor 46, theactivation node 47 is brought to the high logic level, and hence theoutput inverter 50 switches, setting the pump enable signal PE at the second (low) logic level. Theread charge pump 13 is thus deactivated, while the standby charge pump 14 (FIG. 1) is kept in operation to maintain the read voltage VR at the nominal value. In addition, thereset transistor 53 is turned on by thereset inverter 52 and brings thesecond node 42 to the low logic level. Consequently, theactivation transistor 46 is inhibited, while theconfirm transistor 54 starts conducting, so confirming the high logic level present on theactivation node 47. - In practice, the
reset transistor 37, thefirst confirm inverter 40 andsecond confirm inverter 41 defines a bistable type memory circuit, which is set by the power-up signal POR and reset by thereset transistor 53. - When the
memory 1 is started up in the standby state, the enablestage 35 remains in the condition that has been described until a read or write operation is requested. If, instead, thememory 1 is immediately set in the active state and hence the chip enable signal CE has an active value, the control voltage VL supplied by thevoltage regulator 11 oscillates between the first control value and the second control value according to whether the read voltage VR is lower than or equal to the nominal value, as described above with reference to FIGS. 1 and 2. Consequently, theread charge pump 13 is alternately activated and deactivated by the pump enable signal PE, so maintaining the read voltage VR close to the nominal value. - In practice, the pump enable signal PE determines activation of the read
charge pump 13 at powering up of thememory 1 and during reading. - In addition, when the read voltage VR reaches the nominal value and, owing to the presence of the
reset circuit 51, thesecond node 42 goes to the low logic level, the first andsecond confirm inverters first node 39. Consequently, theinput inverter 62 of thesync stage 36 switches and brings the control signal SW to the low logic level, so as to set thetransfer gate 58 in the conduction state and to inhibit thesecond confirm transistor 65. - The chip enable signal CE can thus be brought to the
excitation node 57 and to the inputs of themonostable circuit 60. In particular, if thememory 1 is started up in standby, the chip enable signal CE is at the non-active (high) value, which is equal to the logic level already present on theexcitation node 57 before switching of theinput inverter 62. Consequently, themonostable circuit 60 is not excited and does not generate any pulse (the power-up sync signal ATDS remains low, and reading is not started). - If, instead, a read operation is requested immediately, the chip enable signal CE is set at the active (low) level. Consequently, as soon as the read voltage VR reaches the nominal value, the control signal SW sets the
transfer gate 58 in the conduction state and enables transfer of the active (low) level to the inputs of the monostable circuit 60 (thesecond confirm transistor 65 is inhibited, as explained above). Themonostable circuit 60 is thus excited, and the power-up sync signal ATDS has a pulse of a preset duration, thus determining reading. - The voltage boosting device according to the present invention affords the advantages described in what follows.
- First, the use of the read
charge pump 13 at power-up enables power-up to be speeded up considerably even when thememory 1 is initially set in standby. In fact, theread charge pump 13 has high performance and is able to charge theoutput terminal 10 much faster than thestandby charge pump 14. In addition, the overall consumption of the voltage boosting device is low, in that theread charge pump 13 is deactivated as soon as the read voltage VR reaches the nominal value. - A further advantage is represented by the possibility of generating a power-up sync pulse as soon as the read voltage presents a sufficiently high value. In this way, it is possible to carry out read operations directly at power-up of the
memory 1, without waiting for further clock cycles. - Finally, it is clear that numerous variations and modifications may be made to the voltage boosting device described and illustrated herein, without thereby departing from the scope of the present invention. Hence the invention is to be limited only by the appended claims and the equivalents thereof.
Claims (18)
Applications Claiming Priority (3)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
EP00830088 | 2000-02-08 | ||
EP00830088A EP1124313B1 (en) | 2000-02-08 | 2000-02-08 | Voltage boosting device |
EP00830088.1 | 2000-02-08 |
Publications (2)
Publication Number | Publication Date |
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US20010020839A1 true US20010020839A1 (en) | 2001-09-13 |
US6429634B2 US6429634B2 (en) | 2002-08-06 |
Family
ID=8175170
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Application Number | Title | Priority Date | Filing Date |
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US09/778,330 Expired - Lifetime US6429634B2 (en) | 2000-02-08 | 2001-02-06 | Voltage boosting device, in particular for speeding power-up of multilevel nonvolatile memories |
Country Status (3)
Country | Link |
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US (1) | US6429634B2 (en) |
EP (1) | EP1124313B1 (en) |
DE (1) | DE60025697D1 (en) |
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US20040012263A1 (en) * | 2002-07-22 | 2004-01-22 | Hussein Hakam D. | Method and apparatus for integrated circuit power up |
US20090081699A1 (en) * | 2004-07-21 | 2009-03-26 | Perez Omar D | Methods and compositions for risk stratification |
US20130127436A1 (en) * | 2010-03-16 | 2013-05-23 | Macronix International Co., Ltd. | Apparatus of supplying power and method therefor |
Families Citing this family (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US20110199039A1 (en) * | 2010-02-17 | 2011-08-18 | Lansberry Geoffrey B | Fractional boost system |
Family Cites Families (10)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
KR0127318B1 (en) * | 1994-04-13 | 1998-04-02 | 문정환 | Back bias voltage generator |
DE69616019T2 (en) * | 1996-03-29 | 2002-06-06 | Stmicroelectronics S.R.L., Agrate Brianza | Standby voltage boost level and method for a storage device |
EP0800260B1 (en) * | 1996-03-29 | 2001-10-17 | STMicroelectronics S.r.l. | Voltage booster for memory devices |
JPH09288897A (en) * | 1996-04-19 | 1997-11-04 | Sony Corp | Voltage supplying circuit |
US6101121A (en) * | 1996-06-20 | 2000-08-08 | Stmicroelectronics S.R.L. | Multi-level memory circuit with regulated reading voltage |
EP0906623B1 (en) * | 1996-06-20 | 2001-01-03 | STMicroelectronics S.r.l. | Multi-level memory circuit with regulated writing voltage |
US5880622A (en) * | 1996-12-17 | 1999-03-09 | Intel Corporation | Method and apparatus for controlling a charge pump for rapid initialization |
EP0899742B1 (en) | 1997-08-29 | 2003-11-12 | STMicroelectronics S.r.l. | Method and circuit for generating a gate voltage in non-volatile memory devices |
US6002630A (en) * | 1997-11-21 | 1999-12-14 | Macronix International Co., Ltd. | On chip voltage generation for low power integrated circuits |
DE69912756D1 (en) * | 1999-06-30 | 2003-12-18 | St Microelectronics Srl | Voltage regulator for a capacitive load |
-
2000
- 2000-02-08 DE DE60025697T patent/DE60025697D1/en not_active Expired - Fee Related
- 2000-02-08 EP EP00830088A patent/EP1124313B1/en not_active Expired - Lifetime
-
2001
- 2001-02-06 US US09/778,330 patent/US6429634B2/en not_active Expired - Lifetime
Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US20040012263A1 (en) * | 2002-07-22 | 2004-01-22 | Hussein Hakam D. | Method and apparatus for integrated circuit power up |
US7417335B2 (en) * | 2002-07-22 | 2008-08-26 | Seagate Technology Llc | Method and apparatus for integrated circuit power up |
US20090081699A1 (en) * | 2004-07-21 | 2009-03-26 | Perez Omar D | Methods and compositions for risk stratification |
US20130127436A1 (en) * | 2010-03-16 | 2013-05-23 | Macronix International Co., Ltd. | Apparatus of supplying power and method therefor |
US9423814B2 (en) * | 2010-03-16 | 2016-08-23 | Macronix International Co., Ltd. | Apparatus of supplying power while maintaining its output power signal and method therefor |
Also Published As
Publication number | Publication date |
---|---|
EP1124313B1 (en) | 2006-01-25 |
DE60025697D1 (en) | 2006-04-13 |
EP1124313A1 (en) | 2001-08-16 |
US6429634B2 (en) | 2002-08-06 |
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