JP3667288B2 - Interface buffer - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an interface buffer, and more particularly to an interface buffer that prevents a through current of an interface power source configured with multiple power sources.
[0002]
[Prior art]
In recent years, it is a well-known fact that the operating voltage of electronic devices of information processing apparatuses, in particular electronic devices such as mobile phones, has been lowered in order to reduce power consumption. As a result, it is also well known that the operating voltage of elements used in integrated circuits mounted on these electronic devices, such as transistors, has been decreasing.
[0003]
However, the operating voltage of the interface voltage between the chips of the integrated circuit mounted on these electronic devices cannot be lowered due to the problem of signal transmission. For this reason, the difference between the operating voltage used in the CORE circuit and the operating voltage of the interface is increasing.
[0004]
Further, in order to reduce power consumption, many methods are used to cut off (OFF) the power supply to a chip in a stopped state. Since the interface between the stopped chip and the operating chip remains connected, the interface power supply is still supplied.
[0005]
Therefore, although the power supply of the CORE circuit is turned off, the logic output of the interface needs to output a fixed potential in order to guarantee the operation for the chip in the next operation state.
[0006]
For this reason, it is necessary to reduce the power (prevention of through current) in the power OFF detection block in the CORE region that fixes the output of each interface block when the power of the CORE circuit is OFF and the interface power is ON.
[0007]
A conventional power supply detection circuit for such multiple power supplies is described in, for example, Japanese Patent Application Laid-Open No. 9-205355. The circuit configuration of this conventional power supply detection circuit is shown in FIG. Since the conventional power supply detection circuit does not have an interface buffer with a power supply detection circuit between different potentials, a circuit specially disclosed in Japanese Patent Application Laid-Open No. 9-205355 is applied to the interface buffer. This will be described with reference to FIG.
[0008]
First, the operation of the conventional power supply detection circuit will be described with reference to FIG.
[0009]
When the power supply V1 is OFF and the power supply V2 is ON, the power supply V1 is a power supply that is OFF by the resistor 5 and the Pch transistor 20 because the Pch transistor 20 of the potential fixing circuit 4 is always ON. The potential of the floating power supply V1 becomes GND, the output 6 of the V1 potential fixing circuit 4 becomes GND, the output signal 17Z of the inverter 50 becomes the potential of the power supply V2, and the output S39Z of the OR circuit 39Z becomes the power supply V2 potential fixed. , LD11Z is invalidated.
[0010]
When the power source V1 and the power source V2 are both ON, the Pch transistor 20 of the V1 potential fixing circuit 4 is always ON. Therefore, the output 6 of the V1 potential fixing circuit 4 depends on the resistance ratio between the ON resistance of the Pch transistor 20 and the resistor 5. Although it becomes an intermediate potential, the resistance value of the resistor 5 is sufficiently larger than the ON resistance value of the Pch transistor 20, and the potential rises to near the power source V1, the output 17Z of the inverter 50 becomes GND, and the output S39Z of the OR circuit 39Z varies depending on LD11Z. Then, the LD 11Z is activated. That is, the LD 11Z is switched between valid and invalid by turning on and off the power source V1.
[0011]
Next, an interface buffer with a power supply detection circuit described in JP-A-9-205355 will be described with reference to FIG.
[0012]
The interface buffer with a power supply detection circuit has a 1.5V voltage power supply V1 for the core circuit and a 3.3V voltage power supply V2 for the interface.
[0013]
The power supply detection circuit 51 includes a V1 potential fixing circuit 4 including a resistor 5 and an inverter 50.
[0014]
The interface circuit 10 is a circuit that outputs the output of the CORE circuit 8 to a terminal OUT, and includes an interface level shift circuit 11, a NOR circuit 12, and an output buffer 13.
[0015]
When the power source V1 is OFF and the power source V2 is ON, the Pch transistor 20 of the V1 potential fixing circuit 4 is always ON. Therefore, the power source that is OFF by the resistor 5 and the Pch transistor 20, that is, the power source V1 that is floating. Becomes the GND, the output 6 of the V1 potential fixing circuit 4 becomes GND, the output 17Z of the inverter 50 becomes the potential of the power source V2, and OUT becomes the potential of the power source V2. That is, the V1 potential fixing circuit 4 detects that the power source V1 is turned off, and the inverter 50 converts the level.
[0016]
When both the power supply V1 and the power supply V2 are in the ON state, the Pch transistor 20 of the V1 potential fixing circuit 4 is always ON, so that the output 6 of the V1 potential fixing circuit 4 depends on the resistance ratio between the ON resistance of the Pch transistor 20 and the resistance 5 Although it becomes an intermediate potential, the resistance value of the resistor 5 is sufficiently larger than the ON resistance value of the Pch transistor 20 and the potential rises to near the power source V1, the output 17Z of the inverter 50 becomes GND, and OUT outputs the logic of the CORE circuit 8. .
[0017]
That is, the interface output is controlled according to the ON / OFF state of the power supply V1.
[0018]
However, in the circuit of FIG. 4, when both the power supply V1 and the power supply V2 are in the ON state, the potential of the output 6 of the V1 potential fixing circuit 4 is lower than the potential of the power supply V2, so the Pch transistor 52 of the inverter 50 is not turned off. A current 54 flows between V2 and GND.
[0019]
Furthermore, in recent years, as described above, the potential difference between the power supply of the CORE circuit and the power supply of the interface has increased, and this through current is a current that cannot be ignored.
[0020]
For example, to explain with an example of the through current, the through current due to the V1 potential fixing circuit 4 is mainly determined by the resistor R, but the resistor R is composed of a large resistance of about 1 GΩ, so V1 = 1.5V. Then, the current is about 1.5 nA. In the inverter 50, for example, when the gate-source voltage VGS = 3.3 V, the Pch transistor ION = 0.5 mA, and the Nch transistor ION = 1 mA, the Vch = 1.5 V, the Pch transistor ION = 0.18 mA. ION = 0.36 mA, resulting in a current of about 200 μA. Further, in order to increase the gate length of the transistor to reduce the ON resistance value to several nA, the transistor area is required several hundred times, which is disadvantageous in terms of the occupied area of the chip.
[0021]
Further, to explain the example of the area of the resistance element, in order to configure the resistance of 1 GΩ used in the V1 potential fixing circuit 4 with a resistance element (for example, poly resistance), a length of about 20 mm is required, and 4 mm An area of about ² is required, and using a large number of resistance elements instead of transistor elements is disadvantageous in terms of layout area.
[0022]
Next, a conventional interface buffer with a power supply detection circuit using a circuit used for voltage conversion (level shift) between different potentials, such as the power supply V1 and the power supply V2, without flowing a current between the power supply V2 and GND. Will be described with reference to FIGS. 5 and 6. FIG.
[0023]
FIG. 5 is a circuit that performs voltage conversion (level shift) between different potentials, such as the power supply V1 and the power supply V2, without passing a current between the power supply V2 and GND.
[0024]
The logic signal 60 of the CORE circuit 8 is input to the interface buffer 65. The signal 61 is an inverted signal of the logic signal 60 of the CORE circuit, and the Nch transistor 63 is ON and the Nch transistor 64 is OFF, or the Nch transistor 63 is OFF and the Nch transistor 64 is ON, and the potential of the signal 62 is the power supply V2. Or it is the structure which becomes GND electric potential, and a level shift is performed from the power supply V1 to the power supply V2 without flowing the electric current between the power supplies V2 and GND.
[0025]
FIG. 6 shows an interface buffer with a power supply detection circuit in which the inverter 52 of FIG. 4 is replaced with the level shift circuit of FIG. 5 which prevents the through current.
[0026]
When both the power supply V1 and the power supply V2 are in the ON state, the potential of the output 6 of the V1 potential fixing circuit 4 is the potential of the power supply V1, the potential of the output 3 of the inverter 70 is GND, and the potential of the output signal 17 of the power supply detection circuit 1 is GND. The logic of the CORE circuit 8 is output.
[0027]
When the power source V1 is OFF and the power source V2 is ON, the potential of the output 6 of the V1 potential fixing circuit 4 is GND, and the power source V1 that is the power source of the inverter 70 is GND, so the potential of the output 3 of the inverter 70 is also GND. The transistors 9 and 19 are both turned OFF, the potential of the output signal 17 of the power supply detection circuit 1 is not fixed, and the level output terminal OUT is not fixed.
[0028]
That is, when a conventional level shift circuit for preventing through current of an interface power supply is used, it does not operate as an interface block with a power supply detection circuit.
[0029]
[Problems to be solved by the invention]
However, the prior art has the following problems.
[0030]
When converting from the CORE power source V1 having a low potential to the interface power source V2 having a high potential, if the potential is converted (level shift) only with the interface power source V2 having a high potential, it is necessary to input the low potential to the high potential gate circuit. Yes, the Pch transistor is not completely turned off and a through current flows.
[0031]
When a circuit for converting from a low potential to a high potential in which a through current is prevented is used in a conventional power source detection circuit, a circuit configuration using a CORE power source V1 having a low potential and an interface power source V2 having a high potential in the circuit. Therefore, when the CORE power supply V1 is turned OFF, the output cannot be fixed and there is a problem that the operation becomes unstable.
Therefore, a main object of the present invention is to provide an interface buffer that solves the above-mentioned problems.
[0032]
[Means for Solving the Problems]
The interface buffer of the present invention includes a core circuit that operates at a first power supply potential, an operating voltage that operates at a first power supply potential and a second power supply potential, receives an output of the core circuit, An interface circuit that outputs a level-shifted output corresponding to a first power supply potential, and a power supply detection circuit that operates with the first power supply potential and the second power supply potential and controls the output of the interface circuit. The power source detection circuit controls the output of the interface circuit to a predetermined fixed potential when the first power source is in an off state and the second power source is in an on state, and from the second power source In this configuration, a through current does not flow through the GND.
[0033]
The power supply detection circuit of the interface buffer according to the present invention includes a V1 potential fixing circuit that receives the potential of the first power supply potential and a level shift circuit that receives the potential of the second power supply potential. In response to the output of the V1 potential fixing circuit, the level shift circuit controls the output of the interface circuit to a predetermined fixed potential.
[0034]
In the level shift circuit of the interface buffer according to the present invention, the first and second transistors of one conductivity type are vertically connected to the power supply V2, and the back gate of the third transistor of reverse conductivity type is connected to the power supply V2. An inverter connected to the drain of the second transistor, and the first and second transistors are arranged vertically so that the drain terminal potential of the third transistor is lower than the first power supply potential. It is the structure which adjusts the number of stacking stages.
[0035]
Furthermore, in the interface buffer of the present invention, the first and second transistors of the one conductivity type are Nch transistors, and the third transistor of the reverse conductivity type is a Pch transistor.
[0036]
DETAILED DESCRIPTION OF THE INVENTION
The interface buffer according to the present invention has a CORE (internal) voltage and an interface (external) voltage supplied at different potentials, and the CORE voltage (for example, 1.5 V) <interface voltage (for example, 3.3 V) In order to prevent malfunction of the next-stage chip even when the power supply is turned off and the interface power supply is turned on, the interface power supply is used to output the chip output (interface output) to a fixed potential (power supply voltage or GND). It is an interface buffer including a power supply detection circuit that prevents current.
[0037]
An interface buffer according to an embodiment of the present invention will be described in detail with reference to the drawings.
[0038]
FIG. 1 is a block diagram showing a configuration of an interface buffer according to the first embodiment of this invention.
[0039]
Referring to FIG. 1, the interface buffer according to the first embodiment of the present invention includes a core circuit 8 that operates with a power source V1 for a core circuit having an operating voltage of 1.5V, and a power source V1 and an operating voltage of 3.3V. The interface circuit 10 operates with the interface power supply V2, receives the output 102 of the core circuit 8 and outputs the level-shifted output 103, operates with the power supply V1 and the power supply V2, and controls the through current of the interface circuit 10. And a power detection circuit 1.
[0040]
The interface circuit 10 is a circuit that outputs the output 102 of the core circuit 8 to a terminal OUT103, and includes an interface level shift circuit 11, a NOR circuit 12, and an output buffer 13.
[0041]
The power supply detection circuit 1 includes a level shift circuit 2 that operates with a power supply V2, and a V1 potential fixing circuit 4 that operates with a power supply V1 and includes a resistor 5.
[0042]
The level shift circuit 2 includes an Nch transistor 9, an Nch transistor 19, a Pch transistor 22, a Pch transistor 23, and a vertically stacked inverter 3.
[0043]
The vertical inverter 3 has a different configuration from a normal inverter, and the Nch transistors (14, 15) are vertically stacked and connected to the power source V2. The Pch transistor 16 has a back gate connected to the drain terminal 7 of the Nch transistor 15. ing.
[0044]
The V1 potential fixing circuit 4 includes an Nch transistor 21 and a Pch transistor 20. The Nch transistor 21 has its gate connected to the output of the vertically stacked inverter 3 and its drain connected to the output signal 6 of the V1 potential fixing circuit 4. The Pch transistor 20 has a gate connected to GND, a source connected to the power supply V1, and a rain connected to the output signal 6 of the V1 potential fixing circuit 4.
[0045]
The interface level shift circuit 11 is a circuit that receives the output signal of the CORE circuit 8, boosts the signal at the V1 voltage level to the V2 level, and outputs it as the output signal 18.
[0046]
The NOR circuit 12 is a circuit that performs a logical operation on the output signal 17 of the power supply detection circuit 1 and the output signal 18 of the interface level shift circuit 11. The output buffer 13 logically inverts the output of the NOR circuit 12 and outputs it from the terminal OUT.
[0047]
Next, the operation of the interface buffer according to the first embodiment of the present invention will be described. The interface buffer according to the first embodiment of the present invention has a V1 potential fixing circuit when the power supply V1 is OFF and the power supply V2 is ON. 4 Pch transistor 20 is always ON, the power supply that is OFF by the resistor 5 and the Pch transistor 20, that is, the potential of the floating power supply V1 becomes GND, and the output 6 of the V1 potential fixing circuit 4 is GND, the Nch transistor 24 is turned off, the Pch transistor 16 is turned on, and the output 24 of the inverter 3 outputs the potential of the drain terminal 7 of the Nch transistor 15.
[0048]
At this time, the potential of the drain terminal 7 of the Nch transistor 15 is a potential obtained by dropping the potential of the Nch transistors (14, 15) by the threshold VTn from the power source V2, and when the potential is VX, the potential VX is the power source V1. The potential is as follows. The threshold value VTn of the Nch transistors (14, 15) is about 1.0V, and the potential VX is a value that is about 2V lower than the power source V1 by stacking in two stages.
[0049]
The Nch transistor 9 is turned off and the Nch transistor 19 is turned on by the output 6 of the V1 potential fixing circuit 4 and the potential of the drain terminal 7 of the Nch transistor 15, and the potential of the output signal 17 of the power supply detection circuit 1 is the potential of the power supply V2. Thus, the output of the NOR circuit 12 becomes GND regardless of the output of the CORE circuit 8, and the output terminal OUT is fixed at the potential of the power supply V2.
[0050]
When both the power supply V1 and the power supply V2 are in the ON state, the Pch transistor 20 of the V1 potential fixing circuit 4 is always ON, so the output 6 of the V1 potential fixing circuit 4 is the resistance ratio between the ON resistance of the Pch transistor 20 and the resistance 5 However, the resistance value of the resistor 5 is sufficiently larger than the ON resistance value of the Pch transistor 20, and the potential of the output 6 of the V1 potential fixing circuit 4 rises to near the power source V1.
[0051]
The Pch transistor 16 having the drain terminal 7 of the Nch transistor 15 as the back gate is connected to the power supply V2 through the two stages of the Nch transistors 14 and 15 so that the back gate potential VX is equal to or lower than the power supply V1. Then, it is completely turned off, and the potential of the output 24 of the vertical inverter 3 is set to GND without passing through current to the interface power supply. The Nch transistor 9 is turned ON, the Nch transistor 19 is turned OFF, the potential of the output signal 17 of the power supply detection circuit 1 is set to GND, and OUT outputs the logic of the CORE circuit 8. FIG. 2 shows the second embodiment of the present invention. It is a block diagram which shows the structure of the interface buffer of a form.
[0052]
Referring to FIG. 2, the interface buffer according to the second embodiment of the present invention includes Nch transistors 14 and 15 of the vertically stacked inverter 3 of the interface buffer according to the first embodiment of FIG. Since the other components are the same in the vertically stacked inverter 32 replaced with 35, detailed description thereof is omitted.
[0053]
The interface buffer according to the second embodiment of the present invention adjusts the number of vertically stacked diodes so that the potential VX of the terminal 7 of the diode 35 is lower than the power supply V1. The same effect as the interface buffer of the embodiment can be obtained.
[0054]
FIG. 3 is a block diagram illustrating a configuration of an interface buffer according to the third embodiment of this invention.
[0055]
Referring to FIG. 3, the interface buffer according to the second embodiment of the present invention is different from the interface block level shifter circuit 11 of the interface buffer according to the first embodiment of the present invention shown in FIG. Since the other components are the same in the circuit replaced with, detailed description thereof is omitted.
[0056]
The interface buffer according to the third embodiment of the present invention may be the interface buffer according to the first embodiment of the present invention even if a NOR type level shift circuit in which an interface block and a power supply detection level shifter are combined is used in the interface section. The same effect can be obtained.
[0057]
【The invention's effect】
As described above, the Nch transistors 14 and 15 so that the potential VX of the drain terminal 7 of the Nch transistor 15 of the inverter 3 in the level shift circuit 2 receiving the potential of the power supply V1 is lower than the power supply V1. By adjusting the number of vertical stacked stages, a power supply detection circuit for the internal power supply V1 can be configured without a through current flowing from the interface power supply V2 to the GND.
[0058]
For example, when the CORE potential V1 = 1.5V, the interface voltage V2 = 3.3V, and the VTn of the Nch transistor = 1.0V, by vertically stacking Nch 2 stages, VX = 3.3V−1.0V × 2 = 1. The gate voltage of the Pch transistor 16 that satisfies 3V and VX <V1 is V1 = 1.5V, the source voltage VX = 1.3V, and the gate-source voltage VGS = −0.2V. No. 16 is completely turned off and no through current flows through the inverter 3.
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating a configuration of an interface buffer according to a first embodiment of this invention. .
FIG. 2 is a block diagram illustrating a configuration of an interface buffer according to a second embodiment of this invention.
FIG. 3 is a block diagram illustrating a configuration of an interface buffer according to a third embodiment of this invention.
FIG. 4 is a block diagram showing a configuration of a conventional interface buffer.
FIG. 5 is a block diagram of a through current prevention level shifter according to an embodiment of the present invention.
FIG. 6 is a block diagram showing a configuration of a conventional interface buffer using a through current prevention level shifter.
FIG. 7 is a multi-power supply detection circuit described in Japanese Patent Application Laid-Open No. 9-205355.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Power supply detection circuit 2 Level shift circuit 3 Vertically stacked inverter 4 V1 electric potential fixing circuit 5 Resistance 6 Output 7 Drain terminal 8 CORE circuit 10 Interface circuit 11 Level shift circuit for interface

Claims (8)

A core circuit that operates at an operating voltage of a first power supply potential, and operates at a first power supply potential and an operating voltage of a second power supply potential, receives an output of the core circuit, and corresponds to the first power supply potential An interface circuit that outputs a level-shifted output, and a power detection circuit that operates at the first power supply potential and the second power supply potential and controls the output of the interface circuit,
The power supply detection circuit controls the output of the interface circuit to be a predetermined fixed potential when the first power supply is in an off state and the second power supply is in an on state, and from the second power supply to GND An interface buffer characterized in that a through current does not flow through. The power supply detection circuit includes a V1 potential fixing circuit that receives the potential of the first power supply potential and a level shift circuit that receives the potential of the second power supply potential, and outputs the V1 potential fixing circuit. The interface buffer according to claim 1, wherein the level shift circuit controls the output of the interface circuit to a predetermined fixed potential. In the level shift circuit, first and second transistors of one conductivity type are vertically connected to the power supply V2, and the back gate of the third transistor of reverse conductivity type is connected to the drain of the second transistor. And an inverter
3. The interface buffer according to claim 2, wherein the number of vertically stacked stages of the first and second transistors is adjusted so that the potential of the drain terminal of the third transistor is lower than the first power supply potential. 4. The interface buffer according to claim 3, wherein the first and second transistors of one conductivity type are Nch transistors, and the third transistor of opposite conductivity type is a Pch transistor. The interface buffer according to claim 1, wherein the second power supply potential is higher than the first power supply potential. The interface buffer according to claim 1, wherein the first power supply potential is 1.5V. 5. The interface buffer according to claim 1, wherein the second power supply potential is 3.3V. 5. The interface buffer according to claim 3, wherein the number of vertically stacked stages of the first and second transistors is two.

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