This application is based upon and claims the benefit of the priority of Japanese Patent Application No. 2009-176680, filed on Jul. 29, 2009, the disclosure of which is incorporated herein in its entirety by reference thereto.
The present invention relates to a power supply circuit and a semiconductor device, and in particular, to a power supply circuit that boosts voltage, by a voltage booster circuit, of a power supply supplied from outside, and supplies the power supply as an internal power supply to an internal circuit of the semiconductor device, and relates to a semiconductor device provided with the power supply circuit in question.
Through the miniaturization of transistors that make up semiconductor devices, integration of the semiconductor devices increases and chip sizes shrink, so that reductions in cost become possible.
Along with the miniaturization of transistors, from the viewpoint of reliability, a need has arisen to lower the voltage of power supply voltages applied to circuits that make up the semiconductor devices. Accompanying this, power supply voltages supplied from outside also have their voltages lowered.
Besides logic circuits, a DRAM may also be implemented as internal memory in the semiconductor devices. In general, when data is written to and read from a DRAM cell, it is necessary to apply a relatively high voltage to a gate of a memory cell transistor. Therefore, in a case where the power supply voltage supplied from outside of the semiconductor device has its voltage lowered, it is necessary to generate a high voltage internally in the semiconductor device, for example, by a power supply circuit that includes a voltage booster circuit.
An external power supply VDD (for example, 1.5 V) is supplied to the logic circuit 23, and together with the external power supply VDD, a VPP (for example, 2.5 V), whose voltage is boosted by a power supply circuit, is supplied to the DRAM 22. CLK, which is an external clock, together with a command and address for controlling operation are inputted to the logic circuit 23 and the DRAM 22, and data input and output are performed.
Next, referring to
In the voltage booster circuit 111, the n-type MOSFETs MN0 to MN2 are diode-connected in series, and the capacitive elements C1 and C2 are connected to junctions thereof. Clock signals PCLA and PCLB are received respectively at opposite electrodes of the capacitive elements C1 and C2. The inverter IN1 receives the clock signal PCL, and outputs the clock signal PCLA. The inverters IN2 and IN3 that are connected in series receive the clock signal PCL, and output the clock signal PCLB. The clock signals PCLA and PCLB are complementary signals.
By the clock signal PCL being received, charge is sequentially transferred from VDD to VPP via the n-type MOSFETs MN0 to MN2 that are connected in series, and a high voltage is supplied to VPP.
In the voltage booster circuit 111 shown in
Referring to
Referring to
Next, referring to
Referring to
With regard to the DRAM 22 showing the VPP consumption current characteristic of
A DRAM access waveform in
As an example, assume that a set level of VPP is 2.5 V. Since at time T0 the VPP level is lower than a prescribed level, the output PACT of the high voltage detection circuit 116 is outputted at an H level. Since PACT is at the H level, the NAND circuit NAND11 supplies the clock signal (pumping pulse) PCL to the voltage booster circuit 111, synchronized with the clock CLB. In this way, the voltage booster circuit 111 performs a voltage boosting operation and a high voltage is supplied to the VPP.
As shown in
After this, the level of the VPP decreases due to operation of the DRAM 22, and amounts to less than 2.5 V after time T3. In consideration of the delay time required for judgment of voltage by the high voltage detection circuit 116, the output PACT of the high voltage detection circuit 116 transitions to an H level at time T4. Thereupon, the output PCL of the NAND circuit NAND11 is synchronous with the clock signal CLB. At this time, the clock signal PCL is supplied to the voltage booster circuit 111, and the voltage booster circuit 111 performs a voltage boosting operation and supplies a high voltage to the VPP.
By repeating the above operation, the VPP level is controlled to be in a vicinity of 2.5 V, which is a target value.
JP Patent Kokai Publication No. JP-P2006-185530A (FIG. 4)
The entire disclosure of Non-Patent Document 1 is incorporated herein by reference thereto.
The following analysis is given by the present inventors.
In the abovementioned description, the frequency of a clock signal CLB, oscillated by an internal clock generation circuit 115 is set to a frequency PC. On the other hand, a DRAM 22 of a semiconductor device 20 shown in
The frequency of the external clock CLK may have different values depending on a system in which the semiconductor device 20 is mounted. Therefore, as shown in
In order to guarantee a consumption current IPP2 of the DRAM 22, at the high frequency DC2 at which consumption current is higher, the VPP current supply capability of the power supply circuit 21, which supplies VPP, is designed to be IPPmax. Thus, in a case where the DRAM 22 operates at the low frequency DC1, control with regard to a high voltage side of the VPP becomes difficult, and as described below, there is a problem in that the VPP shifts largely to a high voltage side, and reliability of a device to which the VPP is applied decreases.
As an example, a set level of VPP is 2.5 V, similar to
As shown in
In a time-period from time T1 to time T2, the VPP has an excessive voltage boost. A difference between the VPP current supply capability IPPmax of the voltage booster circuit and the current IPP1 actually consumed (IPPmax−IPP1) in a case where the operating frequency of the DRAM 22 is DC1, is very large in comparison to a difference between the VPP current supply capability IPPmax of the voltage booster circuit and the current IPP2 actually consumed (IPPmax−IPP2) in a case where the operating frequency of the DRAM 22 is DC2 (refer to
Therefore, the amount of excessive voltage boost of the VPP to a high voltage between time T1 and time T2 in
Therefore, there is a need in the art to change the current supply capability of a power supply circuit, in accordance with the amount of current consumed by a circuit supplied with current by the power supply circuit, is a problem. There is also a need to provide a power supply circuit and a semiconductor device that solve this problem.
In a first aspect of the present invention, there is provided a power supply circuit comprising:
a first voltage booster circuit that receives a first clock signal having a fixed frequency, and supplies a voltage to a prescribed circuit; and
a second voltage booster circuit that receives a second clock signal having a frequency corresponding to an operating frequency of the prescribed circuit, and supplies a voltage to the prescribed circuit.
In a second aspect of the present invention, there is provided a semiconductor device comprising the power supply circuit.
The present invention provides the following advantage, but not restricted thereto.
According to the power supply circuit and the semiconductor device of the present invention, it is possible to change the current supply capability of the power supply circuit, in accordance with amount of current consumed by a circuit supplied with current by the power supply circuit.
In the present disclosure, there are various possible modes, which include the following, but not restricted thereto.
A power supply circuit in a first mode is preferably a power supply circuit according to the first aspect.
A power supply circuit in a second mode may further comprise a high voltage detection circuit that detects a voltage supplied to a prescribed circuit by a first voltage booster circuit and a second voltage booster circuit, and in a case where the voltage in question is larger than a prescribed threshold voltage, stops a voltage boosting operation in the first voltage booster circuit and the second voltage booster circuit.
A power supply circuit in a third mode may further comprise an internal clock generation circuit that generates a first clock signal.
In the power supply circuit in a fourth mode, the first voltage booster circuit may output a direct current component in current consumed by the prescribed circuit, and the second voltage booster circuit may output an alternating current component in current consumed by the prescribed circuit.
A power supply circuit in a fifth mode may further comprise a frequency multiplier circuit that receives a clock signal having an operating frequency of the prescribed circuit, and multiply the frequency, which is outputted as the second clock signal.
A power supply circuit in a sixth mode may further comprise a frequency divider circuit that receives a clock signal having an operating frequency of the prescribed circuit, and performs frequency division on the frequency, which is outputted as the second clock signal.
A power supply circuit in a seventh mode may comprise the abovementioned power supply circuit.
A power supply circuit in an eighth mode may further comprise the prescribed circuit.
A description is given concerning a power supply circuit according to a first exemplary embodiment, making reference to the drawings.
The voltage booster circuit 11 supplies an AC current component of a circuit to which VPP is supplied. The high voltage detection circuit 16 judges the VPP level, and controls an output signal PACT. The external clock input circuit 13 receives an external clock CLK, and outputs as a clock signal CLA. The NAND circuit 1 receives the clock signal CLA and the signal PACT as input, and outputs the signal PCL1. The voltage booster circuit 11 receives the signal PCL1.
On the other hand, the voltage booster circuit 12 supplies a DC current component of the circuit to which VPP is supplied. The NAND circuit 2 receives the signal PACT and the clock signal CLB outputted by the internal clock generation circuit 15, and outputs the signal PCL2. The voltage booster circuit 12 receives the signal PCL2.
Similar to a case shown in
The DC current component IPP0 does not depend on operating frequency of the DRAM 22. Furthermore, a fixed small current may be supplied as the DC current component IPP0. Therefore, the voltage booster circuit 12 that supplies the DC current component IPP0 can operate at a high frequency, and it is possible to make the size of this circuit small. Consequently, as shown in
On the other hand, the AC current component changes, depending on the operating frequency of the DRAM 22. Therefore, it is preferable that DC1 and DC2, which correspond to external clock frequencies in
At this time, if the operating frequency of the DRAM 22 changes in a range of from DC1 to DC2, the frequency of the clock signal with respect to the voltage booster circuit 11 also changes from PC1 to PC2 in synchronization with the external clock frequency. Therefore, the difference between the VPP consumption current of the DRAM 22 and the VPP current supply capability of the voltage booster circuit 11 can be made small in comparison to a conventional example shown in
Referring to
The external clock input circuit 13 receives the external clock CLK, and supplies the clock signal CLA of frequency DC2, which is identical to the external clock CLK, to the voltage booster circuit 11.
On the other hand, the internal clock generation circuit 15 supplies the clock signal CLB of a fixed frequency not depending on the external CLK to the voltage booster circuit 12 (in
As an example, a set level of VPP is 2.5 V. Since at time T0 the VPP level is lower than a prescribed level, the output PACT of the high voltage detection circuit 16 is outputted at an H level. Since PACT is at the H level, the NAND circuit NAND1 supplies the clock signal PCL1 to the voltage booster circuit 11 in synchronization with the clock signal CLA (external clock CLK). In this way, the voltage booster circuit 11 performs a voltage boosting operation, and supplies a charge corresponding to the AC current component IPPA2 to the VPP. The NAND circuit NAND2 supplies the clock signal PCL2 to the voltage booster circuit 12 in synchronization with the clock signal CLB. In this way, the voltage booster circuit 12 performs a voltage boosting operation, and supplies a charge corresponding to the DC current component IPP0 to the VPP.
The level of the VPP gradually increases, and is 2.5 V at time T1. In consideration of delay time required for judgment of voltage by the high voltage detection circuit 16, the output PACT of the high voltage detection circuit transitions to an L level at time T2. Thereupon, the output PCL1 of the NAND circuit NAND1 and the output PCL2 of the NAND circuit NAND2 are fixed at the H level, and the voltage booster circuit 11 and the voltage booster circuit 12 stop the voltage boosting operation.
After this, the level of the VPP decreases due to operation of the DRAM 22, and after time T3 is less than 2.5 V. In consideration of the delay time required for judgment of voltage by the high voltage detection circuit 16, the output PACT of the high voltage detection circuit 16 transitions to an H level at time T4. Thereupon, similar to the case at time T0, the voltage booster circuit 11 and the voltage booster circuit 12 perform voltage boosting operations and supply a high voltage to the VPP.
By repeating the above operations, the VPP level is controlled to be in a vicinity of 2.5 V, which is a target value.
Referring to
The external clock input circuit 13 receives the external clock CLK, and supplies the clock signal CLA of frequency DC1, which is identical to the external clock CLK, to the voltage booster circuit 11.
On the other hand, the internal clock generation circuit 15 supplies the clock signal CLB of a fixed frequency not depending on the external CLK to the voltage booster circuit 12 (in
Operation of the power supply circuit in this case is basically the same as for
In the power supply circuit of the present exemplary embodiment, in a case where the external clock CLK stops, the voltage booster circuit 11 stops operation. However, since the internal clock generation circuit 15 continues to output the clock CLB, the DC current component (IPP0 in
In the present exemplary embodiment, the consumption current of the high voltage VPP supplied by the power supply circuit is divided into a DC current component IPP0 that does not depend on an operation period of a supply destination circuit (for example, the DRAM 22), and an AC current component IPPA1 (or IPPA2) that depends on the operation period; the DC current component IPP0 is supplied by the voltage booster circuit 12 that operates by the clock signal (CLB) generated by the internal clock generation circuit 15; and the AC current component IPPA1 (or IPPA2) is supplied by the voltage booster circuit 11 that operates by the clock signal CLA in synchronization with the external clock CLK. In this way, the voltage booster circuit can supply a current corresponding to the consumption current of the supply destination circuit (for example, the DRAM 22). Therefore, even if the operating frequency of the supply destination (a DRAM part) changes, it is possible to stably control the high voltage VPP.
According to the power supply circuit of the present exemplary embodiment, it is possible to realize a power supply circuit having a suitable current supply capability that corresponds to consumption current (from IPPA1 to IPPA2 in the abovementioned example) that changes according to the external clock period, and it is possible to solve a problem in which voltage is excessively boosted in the VPP in a conventional power supply circuit.
That is, in the power supply circuit including the voltage booster circuit that generates high voltage as an internal power supply of the semiconductor device, by performing operation control of the voltage booster circuit corresponding to consumption current at high voltage, it is possible to prevent variations in control level of the high voltage due to change in the consumed current, and in particular, excessive voltage boosting. Furthermore, by preventing excessive voltage boosting, it is possible to prevent variations in circuit characteristic of a circuit supplied with the high voltage, and to prevent decrease in reliability.
A description is given concerning a power supply circuit according to a second exemplary embodiment, making reference to the drawings.
Referring to
By providing the frequency multiplier circuit (or the frequency divider circuit) 14, the external clock CLK and the clock signal CLA supplied to the voltage booster circuit 11 change in synchronization, while maintaining an N times (or 1/N times) relationship. Here, N is a natural number.
According to the power supply circuit of the present exemplary embodiment, based on a frequency characteristic (
The above description has been given based on the exemplary embodiments, but the present invention is not limited to the abovementioned exemplary embodiments.
Within the entire disclosure of the present invention (including the claims), and based on its basic technological idea, exemplary embodiments or examples of the present invention may be changed and/or adjusted. Also it should be noted that within the scope of the claims of the present invention, any combinations or selections of various elements disclosed herein are possible. That is, needless to say, it is understood by those skilled in the art that various changes or modifications can be made to the present invention based on the disclosure of the present invention including the claims and the technological idea of the present invention.
Number | Date | Country | Kind |
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2009-176680 | Jul 2009 | JP | national |