Static information storage and retrieval – Read/write circuit – Including signal comparison
Reexamination Certificate
1999-12-10
2001-08-21
Nguyen, Viet Q. (Department: 2818)
Static information storage and retrieval
Read/write circuit
Including signal comparison
C365S189090, C365S191000, C365S204000, C365S149000
Reexamination Certificate
active
06278638
ABSTRACT:
BACKGROUND OF THE INVENTION
The present invention relates to a pulse generator circuit for outputting a pulse signal of a predetermined pulse width in response to a trigger signal. In particular, the present invention relates to an improvement such that power voltage dependency of a pulse width of a pulse signal is eliminated.
In a semiconductor memory, a pulse signal generated by capturing an address change is employed as a trigger, thereby generating a timing signal of a constant pulse width, and controls the operation of each circuit incorporated in a memory.
FIG. 1
shows a configuration of a conventional pulse generator circuit for generating a pulse signal in response to a trigger signal. This circuit is composed of: the even number of inverters INV
1
to INV
6
(six inverters in this example) connected in cascade; capacitors C connected respectively between an output node of each inverter at an even-numbered stage excluding the last stage and a ground voltage node and between an output node of each inverter at an odd-numbered stage excluding the first stage and a power voltage node; P-channel transistors TP each having a source-drain path inserted between the power voltage node and the output node of an inverter provided at any even-numbered stage but the last-stage, and each having a gate connected to an output node of the first-stage inverter INV
1
; and N-channel transistors TN each having a source-drain path inserted between the ground voltage node and an output node of an inverter provided at any odd-numbered stage but the first stage, and each having a gate connected to an input node of a trigger signal.
FIG. 2
is a timing chart showing an example of operation of the pulse generator circuit shown in FIG.
1
. In the figure, a trigger signal to be input to the inverter INV
1
at the first stage is designated by IN; and signals of the output nodes of the inverters INV
1
to INV
6
at the first to last stages are designated by V
1
, V
2
, V
3
, V
4
, V
5
, and OUT, respectively.
Now, when the signal IN of a pulse width Ta is input, the signals V
1
, V
2
, V
3
, V
4
, V
5
, and OUT are initially set to L, H, L, H, L, and H, respectively.
Next, when the signal IN falls into an L level, the signal V
1
of the output node of the inverter INV
1
at the first stage rises from the initial L level to an H level immediately. Thereafter, a signal V
2
of the output node of the inverter INV
2
at a next stage starts its falling from the initial H level to the L level. However, a capacitor C is connected to its output node, and thus, its falling is gentle.
When the signal V
2
becomes lower than a circuit threshold voltage of the inverter INV
3
at a next stage at a time Tb, the signal V
3
of the output node of this inverter INV
3
starts its rising from the initial L level toward the H level. In this case also, the capacitor C is connected to its output node, and thus, its rising is gentle.
When the signal V
3
becomes higher than a circuit threshold voltage of the inverter INV
4
at a next stage at a time Tc, the signal V
4
of the output node of this inverter INV
4
starts its falling from the initial H level toward the L level. In this case also, its output node is connected to the capacitor C, and thus, its falling is gentle.
When the signal V
4
becomes lower than a circuit threshold voltage of the inverter INV
5
at a next stage, the signal V
5
of the output node of this inverter INV
5
starts its rising from the initial L level toward the H level. In this case also, the capacitor is connected to the output node of the inverter INV
5
, and thus, its rising is gentle.
When the signal V
5
becomes higher than a circuit threshold voltage of the inverter INV
6
at the last stage, the signal OUT of the output node of this inverter INV
6
falls from the initial H level to the L level immediately.
That is, this pulse generator circuit outputs the signal OUT having a predetermined pulse width when a signal IN being a trigger signal is input. The pulse width of the output signal OUT is determined according to: a value of the capacitor C connected to each of the output nodes of the inverters INV
2
to INV
5
; an element size of P-channel transistor and N-channel transistor constituting each inverter for charging and discharging the respective output nodes (N-channel transistors for the inverters INV
2
and INV
4
and P-channel transistors for the inverters INV
3
and INV
5
); and a circuit threshold voltage of each inverter, in particular, a circuit threshold voltage of the inverters INV
3
to INV
6
.
In the meantime, in the conventional circuit shown in
FIG. 1
, a circuit threshold voltage of each inverter or the current driving capacity of the P-channel and N-channel transistors which constitute each inverter varies depending on the value of the power voltage supplied to each inverter. Thus, the pulse width of the output signal OUT has power voltage dependency. For example, when the power voltage is shifted to be higher, the pulse width of the output signal OUT becomes shorter. Conversely, when the voltage is shifted to be lower, the pulse width becomes longer.
Also, assuming that such a pulse generator circuit is provided in a semiconductor memory to control operation of an internal circuit, in a state where a circuit, for example, an equalizing circuit or a latch circuit, is set to be prevented from malfunctioning even when a power voltage is high and a pulse width is short taking in consideration a power voltage dependency of a pulse width of a pulse signal generated at a pulse generating circuit, a pulse width of a pulse signal for controlling operation of the equalizing circuit or the latch circuit becomes long when the power voltage is lowered and the pulse width becomes longer. Thereby, such a problem as increased power consumption or the like will occur in a case that an access time is delayed or a power is lowered.
BRIEF SUMMARY OF THE INVENTION
The present invention has been made in view of the foregoing circumference. It is an object of the present invention to provide a pulse generator circuit capable of outputting a pulse signal having an always constant pulse width without power voltage dependency and a semiconductor memory provided with this pulse generator circuit.
According to the present invention, there is provided a pulse generator circuit comprising: a capacitor in which charging is performed; a charge control circuit for charging the capacitor at a constant current in response to a control signal; and a comparator circuit for comparing the charge voltage in the capacitor with a reference voltage and outputting a pulse signal based on the comparison result.
According to the present invention, there is provided a semiconductor memory comprising: a memory cell array having a memory cell; an address transition detector circuit for receiving address signals for selecting a memory cell of the memory cell array, detecting a switch of the address signals, and generating a pulse signal; a timing control circuit for generating a timing signal in response to a pulse signal generated by the address transition circuit; and a data detector circuit whose operation is controlled based on the timing signal generated by the timing control circuit, the data detector circuit detecting read-out data from the memory cell, wherein the timing control circuit comprises a capacitor in which charging is performed; a charge control circuit for charging the capacitor at a constant current in response to the pulse signal; and a comparator circuit for comparing the charge voltage in the capacitor with a predetermined reference voltage and outputting the timing signal according to the comparison result.
In addition, according to the present invention, there is provided a semiconductor memory comprising: a memory cell array having a memory cell; an address transition detector circuit for receiving address signals for selecting a memory cell of the memory cell array, detecting a switch of the address signals, and generating a pulse signal; a timing control circuit for generating first a
Ikeda Takafumi
Kato Hideo
Tomita Naoto
Hogan & Hartson LLP
Kabushiki Kaisha Toshiba
Nguyen Viet Q.
LandOfFree
Pulse generator circuit and semiconductor memory provided... does not yet have a rating. At this time, there are no reviews or comments for this patent.
If you have personal experience with Pulse generator circuit and semiconductor memory provided..., we encourage you to share that experience with our LandOfFree.com community. Your opinion is very important and Pulse generator circuit and semiconductor memory provided... will most certainly appreciate the feedback.
Profile ID: LFUS-PAI-O-2453084