Electronic circuit for generating a stable voltage signal...

Miscellaneous active electrical nonlinear devices – circuits – and – Specific identifiable device – circuit – or system – With specific source of supply or bias voltage

Reexamination Certificate

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Details

C327S540000

Reexamination Certificate

active

06204722

ABSTRACT:

TECHNICAL FIELD
This invention relates to a stable polarization circuit for UPROM memory cells operating at low voltage.
More specifically, but not exclusively, this invention relates to a circuit for generating polarized signals in the reading of a UPROM redundancy cell incorporating at least one element of EPROM or Flash memory, having at least one polarization terminal, and MOS transistors connecting said memory element to a low voltage source reference.
BACKGROUND OF THE INVENTION
As is well known, the manufacture of non-volatile matrixes with a memory of the so-called EPROM and Flash types has proved to have a relatively low yield.
The prior art attempted to rectify the low yield of the Flash memory production process and the solution adopted so far consists in equipping the cell matrix with additional so called redundancy, which may be used to replace faulty columns and/or rows that show malfunctions after the device has been tested.
Those skilled in the art are familiar with the design and use methodology of redundancy columns and rows as well as of the relative selection circuitry. The latter makes it possible for the memory to be readdressed in such a way as to replace the addresses containing faulty bits by those containing functional bits in the redundancy columns or rows.
At present, the constant evolution of technology and the semiconductor market trend dictate the design of memory devices capable of operating at lower and lower supply voltages.
This gives rise to a number of problems due to the fact that in order to obtain a memory device that is efficient and has a fast response time, particularly in the reading mode, even the redundancy cells and circuitry must meet certain stringent specifications. In particular, the UPROM memory cells incorporated in the selection circuitry, containing the binary code of the addresses to be set as redundant, must be designed to operate efficiently even at low voltages.
In
FIG. 1
, there is illustrated the basic structure of a UPROM
2
memory cell provided between a first reference voltage Vdd and a second voltage reference GND, a ground signal, for example.
Such UPROM cell comprises a memory element represented by an EPROM or Flash type cell FC having a floating gate and containing a binary code of an address to be set as redundant. This cell FC has a conduction terminal, the source terminal, directly connected to ground, while another conduction terminal, the drain terminal, is connected to the power supply Vdd by means of a complementary MOS transistor pair M
1
, M
2
.
The basic structure of the UPROM
2
cell also comprises a latch structure consisting of a first inverter I
1
and a second inverter I
2
each having their respective input and output terminals connected to the output and input of the other inverter.
The first transistor MOS M
1
of the complementary pair is of the P-Channel type and connects the input of the first inverter I
1
with the supply Vdd. The second transistor MOS M
2
is of the N-Channel type and connects the input of the first inverter I
1
to the drain terminal of the cell FC in a source follower configuration.
The control terminal of the FC cell receives a signal UGV, whereas to the respective control terminals G
1
and G
2
of transistors M
1
and M
2
, a signal POR# and a polarization voltage signal VB are applied. The signal POR# represents the NOT form of the start and reset signal POR referred to as POWER ON RESET.
The signal POR is applied to the control terminal G
3
of an enabling transistor M
3
inserted between the output of the first inverter I
1
and ground GND.
Inverters I
1
and I
2
form a latch register and transistors M
1
, M
2
and M
3
allow to effect the start-up step of said latch.
The cell FC is programmed during the testing step, i.e., when the memory devices undergo an EWS (Electrical Wafer Sort) test. Before carrying out any kind of operation on the memory device, all the cells FC of the UPROM circuitry are read, thus enabling correct addressing of the memory cells which are to be replaced.
In order to carry out the reading it is necessary to suitably polarize the terminals of the cell FC.
While operating at low supply voltages Vdd, close to 1.8 Volts, problems arise when generating and controlling the signals necessary to achieve the above mentioned polarization step.
The cells FC incorporated in the UPROM cells generally have a voltage threshold exceeding 2 V, usually of approximately 2.5 V, and a low current absorption; therefore, in order to effect the reading it is necessary to boost the supply voltage Vdd to reach an appropriate voltage level UGV to be applied to the control terminal of the Flash cell type memory element FC.
In order to carry out the reading it is also necessary to supply a correct drain voltage value VB onto the FC cell so as to avoid electrical stresses. Usually, the drain voltage level is set at 1 V.
A known technical solution to generate the voltage levels UGV and VB is described in the European Patent Application No. 95830242.2 in the name of SGS-Thomson Microelectronics S.r.l.
The hereto attached
FIG. 2
illustrates an example of embodiment of a polarization circuit disclosed in that application.
Said circuit, indicated in its whole with the numeral
1
, is responsible for the generation of the signal VBa to be applied to the control terminal of the transistor M
2
of the UPROM
2
cell.
The level of voltage VBa must be such so as to maintain the drain potential of the memory cell FC at approximately 1 V.
Circuit
1
essentially comprises a first section for timing and a second section
8
for generating the voltage VBa.
Generation section
8
, comprises a logical gate P
5
of NOR type inserted in the circuit with a feedback loop
9
.
The output of the logical gate P
5
is connected to the control terminal of a N-channel natural transistor M
10
having a conduction terminal connected to the power supply source Vdd by means of a transistor M
11
and the other conduction terminal connected to ground via transistor M
12
in diode mode connected in turn to another transistor M
13
.
The control terminal of the transistor M
11
is connected to a first input A of the gate P
5
, whereas the node linking transistors M
12
and M
13
are feedback connected to the other input B of the gate P
5
.
The control terminal of transistor M
13
is connected to the output of the first timing section.
Between the transistors M
10
and M
12
there is an output node U
2
from which output voltage VBa is derived; Such output node U
2
is connected to ground via a transistor M
14
in parallel with a stray capacitor C
11
.
The control terminal of this latter transistor M
14
is connected to the first input A of the logical gate P
5
.
When the gate P
5
has a high logic value on one of its inputs, its output will accordingly have a low logic value, which will keep the transistor M
10
switched off. If the input A is high, then the transistor M
14
is switched on and maintains the value of the output node U
2
at ground.
When the transistor M
10
is switched on, on the contrary, current is allowed to pass through the transistors M
10
, M
11
, M
12
. Voltage VBa on the output U
2
can reach the operating level set by the trigger threshold of gate P
5
and by the threshold voltage of the transistor M
12
.
If the voltage VBa were to have a lower value than that indicated, the output of the gate P
5
would allow the transistor M
10
to conduct more current, thus increasing the output voltage value.
If, on the contrary, the voltage VBa were to exceed the chosen value, the feedback input of gate P
5
would have a potential value higher than the trigger threshold of the gate itself, bringing the output to a low potential level and switching off the transistor M
10
. In this way VBa would be reduced until it reaches the pre-set value.
Although for various reasons this could be considered a viable solution, it does not completely fulfill the actual requirements for a correct polarization (that is biasing) of UPROM cells due to a low rejection to the rapid changes of s

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