JPH07249982A - Dynamic logic circuit - Google Patents

Abstract

PURPOSE:To speed the operation of the device by comprising the precharge element by the bell-shift type element and inputting by revers-controlling the clocks of the precharging element and sampling element. CONSTITUTION:When the control clock phi is 'L', the control clock phiX is 'H' and a precharge element 51 is turned on and a sampling element 13 is turned off. A precharge capacitor 65 is precharged. In this case, when the level shift voltage of the element 51 is made VT, the power voltage is VD-VT. Then, when the phi is changed to 'H', the element 51 is turned off and the element 53 is turned on. In this case, if one of the gate input A, B, or C of the N-type MOS transistor of a combination circuit 52 is 'H', the EF are conducted and the output 57 becomes 'L'. The discharge start voltage is VD-VT and the discharge start voltage is low so that the time to reduce the output 57 to the detection level 'L' is shortened.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a high speed dynamic logic circuit device.

[0002]

2. Description of the Related Art FIG. 5 shows a conventional dynamic logic circuit. In FIG. 5, 170 is a precharge element, which is a P-type MOS transistor.

Reference numeral 171 is a combinational circuit, which is an N-type MO.
It is composed of an S transistor (180), an N-type MOS transistor (181) and an N-type MOS transistor (182).

Reference numeral 172 is a sampling element,
Type MOS transistor. 173 is a first power source. 174 is a second power supply (the case is grounded).

Reference numeral 183 denotes a precharge capacitor, which is a gate capacitance of a MOS transistor, a stray capacitance of an output line, and the like. Alternatively, a capacitor may be connected. In the combination circuit 171, each of 180, 181, and 182 is an N-type MOS transistor.

The operation of the dynamic logic circuit of FIG. 5 will be described. When the control clock signal φ is L, the precharge element 170 is turned on and the sampling element 172 is turned off. As a result, the precharge capacitor 183 is charged. Next, when the control clock signal φ is inverted, the precharge element 170 is turned off and the sampling element 172 is turned on. At this time, the combination circuit 171
Each element (N-type MOS transistor (180), N-type M)
If any one of the gate inputs A, B, and C of the OS transistor (181) and the N-type MOS transistor (182) is H, the EFs are electrically connected, so that the charge accumulated in the precharge capacitor 183 is Ground through the N-type MOS transistors (180, 181, 182) 17
4 and the output becomes L. If all of A, B, and C are L, there is no conduction between EFs, so the output is maintained at H.

[0007]

As described above, the dynamic logic circuit operates by repeating charging and discharging of the output precharge capacitor. Therefore, when the circuit becomes complicated, the stray capacitance increases, the capacitance of the precharge capacitor increases, and there is a problem that the operation is delayed. In addition, in order to speed up the charging and discharging of the precharge capacitor, there is one that inserts a level shift element between the precharge element and the power supply terminal to lower the voltage of the precharge capacitor to increase the speed. There is a problem that the pre-charge time becomes long because the circuit area is additionally required by the amount of the inserted elements and the level shift element is inserted in the pre-charge circuit.

An object of the present invention is to provide a dynamic logic circuit device which operates at high speed without adding a level shift element in addition to a precharge element.

[0009]

According to the present invention, a precharge element is composed of a level shift type element, and the precharge element and the sampling element have the same on / off characteristics with respect to a control clock voltage. By configuring the control clock of the precharging element and the control clock of the sampling element to be inverted and input, the charging and discharging of the precharge capacitor can be accelerated without increasing the number of elements.

FIG. 1 shows the basic configuration of the present invention. Figure 1 (a)
Is a configuration for precharging the precharge capacitor to H level and detecting L level.

Reference numeral 1 denotes a precharge element, which is a level shift type element, which outputs a voltage lower than the voltage of the first power source 5 when it is on (for example, N type M).
OS transistor).

Reference numeral 2 is a combinational circuit. A sampling element 3 is, for example, an N-type MOS transistor. 5 is a first power supply.

Reference numeral 6 is a second power supply (the voltage of the second power supply is lower than the voltage of the first power supply). 7 is an output.

Reference numeral 8 is an input 1, which is an input of a control clock for controlling on / off of the precharging element 1.
Reference numeral 9 denotes an input 2, which is an input of a control clock for controlling ON / OFF of the sampling element 3.

10 is a precharge capacitor,
The gate capacitance of the MOS transistor, the floating capacitance of the output line, and the like. A capacitor may be connected. The operation of FIG. 1A will be described later.

FIG. 1B shows a configuration in which the precharge level of the precharge capacitor is L and the H level is detected. In FIG. 1 (b), numeral 11 is a pre-charging element having an output voltage higher than the second power supply voltage when turned on (for example, a P-type MOS transistor).

Reference numeral 12 is a combinational circuit. A sampling element 13 is, for example, a P-type MOS transistor.

Reference numeral 15 is a first power source. Reference numeral 16 is a second power supply (the voltage of the second power supply is lower than the voltage of the first power supply).

Reference numeral 17 is an output. Reference numeral 18 denotes an input 1, which is an input of a control clock for controlling ON / OFF of the precharge element 11.

Reference numeral 19 denotes an input 2, which is an input of a control clock for controlling ON / OFF of the sampling element 13. 20 is a precharge capacitor.

[0021]

The operation of the configuration of FIG. 1 (a) will be described. It is assumed that the precharging element 1 and the sampling element 3 perform the same operation with respect to the control clock voltage of H or L (for example, both are turned on by H and turned off by L). . Then, assuming that the precharge element 1 is level-shifted and the level shift voltage when it is on is V _T and the first power supply voltage V _D , the output voltage when it is on is V _D −V _T.

When φ = L, the control clock φX of the precharge element 1 (representing the negation of φ, the same applies hereinafter) is H, and the control clock of the sampling element is L. Therefore, the precharge element 1 is turned on, the sampling element 3 is turned off, and the precharge capacitor 1 of the output 7 is turned on.
0 is precharged to H. At this time, the voltage of the output 7 is V _D −V _T.

Next, when the control clock φ changes to H, the precharging element 1 is turned off and the sampling element 3 is turned on. At this time, if the combination circuit 2 is on and the EFs are electrically connected, the charge of the precharge capacitor 10 of the output 7 is discharged to the second power source 6 via the combination circuit 2 and the sampling element 3. The output 7 becomes L.

The voltage at the start of discharge of the output 7 is V _D -V _T , and is V _D in the case of the conventional circuit in which the precharge element 1 is not the level shift type, so that the output 7 is detected as L. It takes less time to reach the level.

This point will be described with reference to FIG. In FIG. 2A, V _D is the voltage of the first power supply 5.

V _L is an L level detection voltage. The output voltage when the precharge capacitor 10 of the circuit of the present invention is precharged is V _D -V _T , and the output voltage when the precharge capacitor of the conventional circuit is precharged is V _D.

Time t₀Control clock changes from H to L
Then, the precharge capacitor 10 starts discharging,
The output gradually decreases. In the case of the present invention,
Tick t ₁At L detection level V_LReach Conventional circuit field
In the case of time t₂At L detection level V_LReach this
As described above, according to the present invention, the output voltage is shorter than the conventional circuit.
The detection level is reached and the operation becomes faster.

Next, the operation of FIG. 1 (b) will be described. The precharging element 11 and the sampling element 13 operate in the same manner with respect to an H or L control clock voltage. For example, both are turned on at L, turned off at H, and are level-shifted so that the output voltage when on is higher than the voltage of the second power supply 16 (for example,
P-type MOS transistor). Precharge element 11 the level shift voltage of the on V _T ', the first power supply voltage V _D.

When φ = L, the control clock φX of the input 1 (18) of the precharging element 11 is H and the control clock φ of the input 2 (19) of the sampling element 13 is L. Therefore, the precharge element 11 is turned on, the sampling element 13 is turned off, and the precharge capacitor 20 is precharged to the L level. At this time, the voltage of the output 17 becomes higher than the voltage of the second power supply 16 by V _T ′.

Next, when the control clock φ changes to H, the precharge element 11 is turned off and the sampling element 3 is turned on. At this time, if the combinational circuit 2 is on and the EFs are electrically connected, the precharge capacitor of the output 7 is charged by the first power supply 15, and the voltage of the output 17 gradually increases.

At this time, the charge start voltage of the precharge capacitor is V _T '. On the other hand, the charge element 11
In the case of the conventional circuit which is not the level shift type, the voltage of the precharge capacitor at the start of charging is 0V. Therefore, in the present invention, the time from the start of charging to reaching the H detection level is short, and the operation is speeded up.

This operation will be described with reference to FIG. V _D
Is the voltage of the first power supply 15. V _H is the H level detection voltage.

V _T 'is the level shift voltage of the precharge element 11. The voltage when the precharge capacitor 20 of the circuit of the present invention is precharged is V _T '. At time t ₀ , charging of the precharge capacitor 20 is started.

At this time, in the circuit of the present invention, when charging is started
Precharge voltage is V_T’, And at time t₁At H
Out level V_HTo reach. Conventional dynamic logic circuit
In the case of a device, the discharge opening of the precharge capacitor 20
The starting voltage is 0 V and the time t ₃H level detection voltage V
_HTo reach.

Therefore, in the present invention, the time required for the output 7 to reach the H level detection voltage is shortened, and the operation speed is increased.

[0036]

FIG. 3 shows an embodiment of the present invention. Figure 3 (a) shows
This is a configuration in which the precharge capacitor is charged to H level and L level is detected.

In FIG. 3A, reference numeral 51 is a precharge element, which is an N-type MOS transistor, and has a level shift voltage V _T when it is on.

Reference numeral 52 is a combination circuit. Reference numeral 53 is a sampling element, which is an N-type MOS transistor. 55 is a first power supply.

Reference numeral 56 is a ground. 57 is an output. 6
5 is a precharge capacitor.

In the combination circuit 52, 60, 61,
Reference numerals 62 are N-type MOS transistors, respectively. Figure 3
The operation of the configuration (a) will be described.

When φ = L, the control clock φX of the precharge element 51 is H and the control clock of the sampling element 53 is L. Therefore, the precharge element 51 is on, the sampling element 53 is off, and the precharge capacitor 65 is precharged. At this time, the output voltage is V _D −V _T.

Next, when the control clock φ changes to H, the precharging element 51 is turned off and the sampling element 53 is turned on. At this time, N of the combination circuit 52
If any one of the gate inputs A, B, and C of the MOS transistor is H, the EF is electrically connected, so that the output 57 becomes L at that time. The discharge start voltage is V _D -V
_{At T} , the time required for the output 57 to drop to the L detection level is shorter than that of the conventional dynamic circuit. If all of the gate inputs of the combinational circuit are L, EF will not conduct and output 57 will be held high.

FIG. 3B shows a configuration in which the precharge level of the precharge capacitor is L and the H level is detected. In FIG. 3 (b), 71 is a precharge element, which is a P-type MOS transistor, and has a level shift voltage V _T 'when turned on.

Reference numeral 72 is a combinational circuit. A sampling element 73 is a P-type MOS transistor. 75 is a first power supply.

Reference numeral 77 is an output. In the combination circuit 72, 80, 81 and 82 are P-type MOS transistors, respectively.

Reference numeral 85 is a precharge capacitor. Figure
The operation of the configuration of 3 (b) will be described. When φ = H,
The control clock φX of the charger element 71 is L, and
The control clock φ of the pulling element 73 is H. Obey
The pre-charging element 71 is turned on and the sampling element is
The child 73 is turned off. At that time, precharge capacitor
85 is precharged to L level and output 77 goes to L
(The output voltage is V _T’). Next, change the control clock φ to L
The precharge element 71 is turned off and the sump
The ring element 73 is turned on. At this time, the combination circuit
72 N-type MOS transistor gate inputs A, B, C
If any one of them is H, it will conduct between EF.
The precharge capacitor is charged by the first power supply 75.
The output voltage gradually increases. Discharge at this time
Start voltage is V_D-V_T’, And the output 77 is the detection level of H.
Bell V_HThe time it takes to reach
It is shorter than the logic circuit. All of the gate inputs of the combinational circuit are H
If so, EF does not conduct, so output 77 is held at L
To be done.

FIG. 4 shows FIG. 3 (a) (invention) and FIG. 5 (conventional).
Represents the operation of. The precharge capacitor is precharged at time t ₀ and discharged at time t ₁ . Whereas the conventional precharge voltage is V _D , in the present invention it is V _D -V _T. Therefore, the rate of decrease of the output voltage after starting the discharge at time t ₁ is faster in the present invention than in the case of the conventional circuit device.

[0048]

According to the present invention, when the precharge capacitor is precharged to the H level and then discharged to detect the L level, the discharge start voltage is low, so that the L level detection time can be shortened. . In addition, the pre-charge capacitor is pre-charged to L level before charging,
Even when the H level is detected, since the voltage at the start of charging is high, the time until the H level is detected can be shortened.

Furthermore, since it can be realized without adding a special element, the area for arranging the elements does not increase. Also,
There is no increase in precharge time that would occur when a special element is added.

[Brief description of drawings]

FIG. 1 is a diagram showing a basic configuration of the present invention.

FIG. 2 is an operation explanatory diagram of the basic configuration of the present invention.

FIG. 3 is a diagram showing an example of the present invention.

FIG. 4 is an operation explanatory diagram of the embodiment of the present invention.

FIG. 5 is a diagram showing a conventional dynamic logic circuit.

[Explanation of symbols]

 1: Precharge element (level shift type) 2: Combination circuit 3: Sampling element 5: First power supply 6: Second power supply 7: Output 8: Input 1 9: Input 2 10: Precharge capacitor 11: Precharge element (level shift type) 12: Combination circuit 13: Sampling element 15: First power supply 16: Second power supply 17: Output 18: Input 1 19: Input 2 20: Precharge capacitor

Claims (6)

[Claims] 1. A precharge element (1), a combinational circuit (2) of logic elements and a sampling element (3) are connected in series to connect a first power source (5) and a second power source (6). Insert the precharging element (1) so that it is on the side of the first power supply (5),
The voltage of the first power supply (5) shall be higher than the voltage of the second power supply (6), and the dynamic logic that extracts the output from the connection point (E) between the precharging element (1) and the combinational circuit (2). In the circuit device, the precharging element (1) is a level shift type element whose output voltage when turned on is lower than the voltage of the first power supply (5), and the precharge capacitor (10) is precharged. A dynamic logic circuit device characterized in that the output voltage when the switch is turned on is lower than the voltage of the first power supply (5). 2. The precharge element according to claim 1.
The on / off characteristics of (1) and the sampling element (3) operate in the same manner with respect to the control clock voltage, and the control clock voltage of the precharging element (1) and the sampling element (3) are the same. A dynamic logic circuit device characterized in that the control clock voltage is inverted with respect to one side. 3. A dynamic logic circuit device according to claim 1, wherein the precharging element (1) and the sampling element (3) are constituted by an n-type semiconductor device. 4. A first power source (15) and a second power source (16) are formed by connecting a combination circuit (12) of a precharge element (11) and a logic element (12) and a sampling element (13) in series. Insert the pre-charging element (11) so that it is on the side of the second power supply (16), the voltage of the first power supply (5) is higher than the voltage of the second power supply (6), Precharge element (11) and combination circuit
In the dynamic logic circuit device which takes out the output from the connection point (F) with (12), the precharge element (11) has a level at which the output voltage when it is on is higher than the voltage of the second power supply (16). A dynamic logic circuit device comprising a shift type element, wherein the output voltage when the precharge capacitor (20) is precharged is higher than the voltage of the second power supply (16). 5. The device for precharge according to claim 4.
(11) and the sampling element (13) have the same ON or OFF operating characteristics with respect to the control clock voltage, and the control clock voltage of the precharging element (11) and the control clock voltage of the sampling element (13) are the same. A dynamic logic circuit device in which the other is inverted with respect to the other. 6. The precharge element (11) and the sampling element (13) according to claim 4 or 5,
A dynamic logic circuit device characterized by comprising a semiconductor device.