Boosting circuit

A boosting circuit includes at least two capacitive elements, a first switching element, and second and third switching elements. The first switching element series-connects the capacitive elements. The second and third switching elements respectively supply different power supply potentials to one terminal and the other terminal of each capacitive element.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a boosting circuit and, more particularly, to a boosting circuit with high efficiency used for a power supply circuit.

2. Description of the Prior Art

Another potential higher as an absolute value than an original potential is often generated from a single power supply. A circuit constituted for this purpose is called a boosting circuit.

Important points for comparing the performances of the boosting circuits are roughly classified as follows.

The first point is boosting ability. This point includes whether the boosting circuit has an ability of sufficiently supplying a higher boosted potential and whether the circuit can supply a sufficient current.

The second point is current consumption. When a current consumption value other than a current value actually consumed as a boosting power supply is large even if a sufficiently boosted potential can be obtained, the boosting circuit is very poor in practicability.

The third point is efficiency. The efficiency includes two meanings; one is a boosted potential with respect to current consumption, which is referred to in the second point, and the other is complexity of elements constituting the circuit. In actually constituting the boosting circuit, it is often formed on a semiconductor substrate. At this time, an arrangement which affects the chip size, such as an arrangement using many elements, is inefficient in cost.

Boosting circuits have been developed from these viewpoints, and a typical example is disclosed in Japanese Unexamined Patent Publication No. 11-110989.

Conventional boosting circuits are variously elaborated to increase the boosting efficiency, and the fundamental principle of their boosting scheme is the form of a boosting circuit shown in FIGS. 1 , 2 A, and 2 B. This boosting circuit will be exemplified and explained as a prior art.

FIG. 1 is a circuit diagram showing a conventional boosting circuit.

FIGS. 2A and 2B are waveform charts showing the operation waveforms of the conventional boosting circuit shown in FIG. 1 .

When power supply potentials represented by waveforms as shown in FIG. 2A are input to the contacts CK 7 - 1 to CK 7 - 4 of the circuit shown in FIG. 1 , the boosting circuit performs boosting operation as represented by the line OUT 7 - 1 shown in FIG. 2 B. On each line in FIG. 2A , the lower line represents L level, and the upper line represents H level.

Boosting operation of the conventional boosting circuit will be explained as follows by a boosting unit made up of the transistors N 7 - 1 and N 7 - 5 , and electrostatic capacitive elements CP 7 - 1 and CP 7 - 5 as an example of a minimum unit.

While the contact CK 7 - 3 is at L level, the contact CK 7 - 2 is changed from L level to H level. At this time, the transistor N 7 - 5 is turned on, and the power supply potential serves as a boosting electrostatic capacitance via the transistor N 7 - 5 to charge the electrostatic capacitive element CP 7 - 5 .

Upon completion of charging, the contact CK 7 - 2 drops to L level again, and the transistor N 7 - 5 is turned off. After that, the contact CK 7 - 3 is changed to H level to generate a boosted potential of 2 VCC level as far as the parasitic capacitance is ignored.

In this prior art, four boosting units are connected and can output a boosted potential of 5 VCC level.

The boosting circuit using this conventional method has the following drawbacks.

To establish the conventional boosting circuit, electric charges to be boosted must move via transistors. In the above example, boosted charges pass through the transistors N 7 - 5 , N 7 - 6 , N 7 - 7 , and N 7 - 8 to boost the potential stepwise.

To realize this movement, the contacts CK 7 - 3 and CK 7 - 4 are clocked. As a result, electric charges which have been used once for boosting are wasted. For example, electric charges which are stored in the electrostatic capacitive element CP 7 - 5 from the contact CK 7 - 3 in order to boost the potential by the electrostatic capacitive element CP 7 - 5 are inevitably wasted to draw new boosting charges from the power supply.

As the potential is boosted higher and higher, current consumption greatly increases before no sufficiently boosted potential is output.

As another drawback, a boosting electrostatic capacitance is difficult to form when such a boosting circuit is implemented on a semiconductor substrate. The main factor of increasing the semiconductor cost is the area of a portion constituting a circuit. On the assumption that a high potential is output, a high potential is applied across the electrostatic capacitance. To prevent destruction by a high electric field, a film forming the electrostatic capacitive element must be made thick. This inevitably increases the area of the electrostatic capacitive element, resulting in high cost.

SUMMARY OF THE INVENTION

The present invention has been made in consideration of the above situation, and has as its object to provide a boosting circuit which requires lower current consumption than a conventional boosting circuit.

It is another object of the present invention to provide a boosting circuit which requires a smaller area on a semiconductor substrate than a conventional boosting circuit.

To achieve the above objects, according to the present invention, there is provided a boosting circuit comprises at least two capacitive elements, a first switching element for series-connecting the capacitive elements, second and third switching elements for respectively supplying different power supply potentials to one terminal and the other terminal of each capacitive element, and means for applying a predetermined power supply potential to one capacitive element out of the capacitive elements using the second and third switching elements, series-connecting remaining capacitive elements by the first switching element except for connection with the capacitive element which receives the predetermined power supply potential by the second and third switching elements, and sequentially changing switching states of first, second, and third switching portions to switching states next to corresponding timings.

In the present invention, a boosted potential is obtained by series-connecting boosting electrostatic capacitances. The respective electrostatic capacitances have means for charging the electrostatic capacitances with the power supply potential and switches for series-connecting the electrostatic capacitances. After charging, the electrostatic capacitive elements are series-connected to discharge a boosted potential, and then repetitively charged with the power supply potential. Since electric charges used for boosting are finally extracted as output charges, no electric charges are wasted except for electric charges drawn to a parasitic capacitance.

The electric field applied to each boosting electrostatic capacitive element does not exceed a potential difference between the power supply potential and the ground potential, so that a film forming each boosting electrostatic capacitive element can be set to a small thickness. Particularly when a boosting circuit is to be formed on a semiconductor substrate, the cost can be reduced.

As is apparent from the above aspects, the present invention can reduce current consumption and cost, compared to the prior art in which the boosting circuit is formed on a semiconductor substrate.

As for reduction in current consumption, all the electric charges which are stored in a boosting electrostatic capacitance are finally output in the boosting circuit of the present invention. For this reason, no electric charges are wastefully discharged, and a large reduction in current consumption can be expected, compared to the prior art.

As for cost reduction, when a boosting circuit is formed on a semiconductor substrate, formation of an electrostatic capacitive element costs most because its area is large.

As a method of reducing the area, the film thickness between parallel plates forming the electrostatic capacitance is set small. In the prior art, however, if the boosting potential rises, the potential difference is directly applied across the electrostatic capacitance to destruct the film. Thus, a decrease in film thickness is limited. To the contrary, in the present invention, no electrostatic capacitive element receives any electric field equal to or higher than the potential difference between the power supply potential and the ground potential. The film thickness can be set small, and the area of the electrostatic capacitive element can be reduced.

The above and many other objects, features and advantages of the present invention will become manifest to those skilled in the art upon making reference to the following detailed description and accompanying drawings in which preferred embodiments incorporating the principle of the present invention are shown by way of illustrative examples.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

FIG. 3 is a circuit diagram showing the first embodiment of a boosting circuit according to the present invention.

The circuit diagram of FIG. 3 will be explained simply.

Reference symbols CK 1 - 1 to CK 1 - 4 denote fundamental clocks for supplying potentials to switching potential generation self-boot capacitances for controlling series connection of boosting capacitive elements; CK 1 - 5 to CK 1 - 8 , fundamental clocks for driving boosting electrostatic capacitances; and OUT 1 - 1 , a contact for outputting a boosted potential.

Reference symbols N 1 - 1 to N 1 - 4 denote Nch transistors for charging the boosting electrostatic capacitances with a boosting power supply potential; and N 1 - 5 to N 1 - 8 . Nch transistors for setting a ground potential.

Pch transistors P 1 - 9 to P 1 - 12 are elements for controlling series connection of boosting electrostatic capacitive elements CP 1 - 5 to CP 1 - 8 . Pch transistors P 1 - 1 to P 1 - 8 and electrostatic capacitive elements CP 1 - 1 to CP 1 - 4 are elements for setting a basic potential for controlling the gate potential of the transistors P 1 - 9 to P 1 - 12 .

Reference numerals D 1 - 1 to D 1 - 4 denote diode elements for outputting boosted potentials to the contact OUT 1 - 1 .

The operation of this embodiment will be described with reference to FIGS. 3 , 4 A, and 4 B.

FIGS. 4A and 4B are waveform charts showing the operation waveforms of the boosting circuit shown in FIG. 3 . When power supply potential clocks represented by waveforms as shown in FIG. 4A are input to the contacts CK 1 - 1 to CK 1 - 8 of the circuit shown in FIG. 3 , the boosting circuit performs boosting operation as represented by the line OUT 1 - 1 shown in FIG. 4 B. On each line in FIG. 4A , the lower line represents L level, and the upper line represents H level.

In the boosting circuit of this embodiment, respective electrostatic capacitive elements store electric charges, and series-connected to output a resultant boosted potential. The discharged electrostatic capacitive elements are charged again, and newly series-connected again to output a re-boosted potential.

Before a description of this operation, the operation of a circuit group serving as a boosting unit will be explained.

The basic unit is exemplified by a circuit group made up of the transistors N 1 - 1 , N 1 - 5 , P 1 - 1 , P 1 - 5 , and P 1 - 9 and electrostatic capacitive elements CP 1 - 1 and CP 1 - 5 . The operation of this basic circuit group includes two operations; the first operation is charging operation of electric charges, and the second operation is boosting operation.

Charging operation of electric charges as the first operation is charging operation of boosting charges. In this example, charging operation is done when the contact CK 1 - 5 is at H level. Since both the transistors N 1 - 5 and N 1 - 1 are turned on when the contact CK 1 - 5 is at H level, the electrostatic capacitive element CP 1 - 5 stores electric charges. At this time, the contact CK 1 - 4 is set to H level, and the transistor P 1 - 12 is OFF, which prevents electric charges from flowing into the ground power supply via the transistor P 1 - 12 .

Boosting operation as the second operation is as follows. Boosting operation of the boosting circuit according to this embodiment is performed by series-connection of electrostatic capacitances. That is, the contacts CK 1 - 5 and CK 1 - 1 are set to L level to turn off the transistors N 1 - 5 and N 1 - 1 and turn on the transistor P 1 - 9 . Accordingly, the electrostatic capacitive element CP 1 - 5 is series-connected to the electrostatic capacitive element CP 1 - 6 .

Under this control, power supply potential clocks having waveforms as shown in FIGS. 4A and 4B are input to sequentially charge the series-connected electrostatic capacitive elements CP 1 - 5 to CP 1 - 8 with electric charges. Boosted charges are output via the diode elements D 1 - 1 to D 1 - 4 .

FIG. 5 is a circuit diagram showing the second embodiment of a boosting circuit according to the present invention.

FIGS. 6A and 6B are waveform charts showing the operation waveforms of the boosting circuit shown in FIG. 5 .

FIG. 7 is a circuit diagram showing a circuit group at a portion in the second embodiment shown in FIG. 5 different from that in the first embodiment shown in FIG. 3 .

FIG. 8 is a waveform chart showing the operation waveforms of the circuit group shown in FIG. 7 .

The basic operation and input waveforms in the second embodiment are the same as those in the first embodiment. The second embodiment adds a circuit for further increasing the boosting rate, compared to the first embodiment.

FIG. 7 shows the basic arrangement of the added circuit group.

The purpose of inserting this circuit is to supply a potential equal to or higher than the power supply potential to the gate of a power supply potential charging transistor, e.g., transistor N 3 - 1 and apply to a boosting electrostatic capacitance not an output obtained by subtracting a threshold potential to an Nch transistor but the power supply potential itself, thereby attaining a sufficiently charge potential.

The operation is shown in FIG. 8 . When the contact PT 5 - 1 changes from H level to L level, the contact PT 5 - 2 changes to H level. At this time, the contact PT 5 - 4 tries to change to H level, but the output potential is output with a decrease corresponding to the threshold potential of the transistor N 5 - 1 . Thereafter, when the delay element DL 5 - 1 outputs H level, the contact PT 5 - 4 is boosted to the power supply potential or more by the electrostatic capacitive element CP 5 - 1 owing to capacitive coupling. Since the transistor N 5 - 1 is OFF, the potential of the contact 5 - 4 is held.

By inserting this circuit, the power supply potential charging transistors N 3 - 1 to N 3 - 4 can supply sufficient potentials to their electrostatic capacitances. As a result, a higher boosting rate can be realized.

Note that each of the above-described embodiments has described only a boosting circuit on a positive potential side. An arrangement in which a negative potential is output using the same method also falls within the spirit and scope of the present invention.