Abstract:
A biasing structure for a memory cell storage element, for setting an operating voltage at an accession electrode of the memory cell storage element. The biasing structure includes a biasing transistor coupled to the accession electrode and adapted to set the operating voltage based on a biasing voltage received at a control electrode of the biasing transistor, and a biasing voltage generator for generating the biasing voltage. The biasing voltage generator includes a feedback voltage regulation structure adapted track changes in a threshold voltage of the biasing transistor, so as to keep the operating voltage at the accession electrode of the memory cell storage element substantially stable against operating condition changes.

Description:
PRIORITY CLAIM 
   This application claims priority from European patent application No. 04290446.6, filed Feb. 19, 2004, which is incorporated herein by reference. 
   TECHNICAL FIELD 
   The present invention relates in general to the field of integrated circuits, and particularly to semiconductor memories. Specifically, the invention concerns a biasing structure for biasing memory cell storage elements, particularly but not limitatively electrically-programmable and non-volatile memory cells, in order to access the memory cell for performing operations such as reading out the memory cell content. 
   BACKGROUND 
   A wide class of electrically-programmable non-volatile semiconductor memories have memory cells exploiting as storage elements MOS transistors having a charge retention element such as a polysilicon floating gate or a nitride layer, which can be charged by e.g. injection or tunneling of electric charges (electrons), typically from the MOS transistor channel or drain region. 
   The amount of charge in the charge retention element affects the MOS transistor threshold voltage; this mechanism is exploited for storing information in the memory cell. 
   The information stored in a memory cell can be retrieved by determining the MOS transistor threshold voltage, for example by biasing the MOS transistor in a predetermined condition and sensing the current flowing therethrough. 
   Programming one such memory cell involves applying to the MOS transistor suitable programming potentials, in particular to the control gate and the drain electrodes thereof. 
   In general, the programming potentials are relatively high compared to the electric potentials (read potentials) that are applied to the transistor electrodes for reading the information stored therein. 
   Great care is however to be adopted in controlling the read potentials applied to the memory cell storage elements; in fact, if these potentials are too high, a spurious injection of charges into the MOS transistor&#39;s charge retention element may take place, which alter the amount of charge in the charge retention element and thus the MOS transistor threshold voltage; this effect, usually referred to as “soft” programming, may cause an initially non-programmed memory cell storage element to become programmed. If this occurs, the data stored in the memory cell, and thus in the memory device as a whole, are corrupted. 
   In particular, in order to avoid or at least limit the risk of soft programming, it is necessary to carefully control the memory cell storage element drain potential: if the drain potential is not sufficiently low, the memory cell storage element is said to experience a drain stress, and this may induce the injection and/or tunneling of charges into the charge retention element. 
   The effect of drain stress on soft programming is particularly felt when the memory cell undergoes a large number of read accesses, and/or when the read potentials are applied to the memory cell for a relatively long time. 
   Conventionally, a biasing transistor is placed in series with the memory cell storage element, having the function of biasing the drain of the storage element. The biasing transistor, typically an N-channel MOSFET, is controlled by a biasing voltage which, typically, is generated by means of a voltage partition from an initially higher voltage, which can be the supply voltage (VDD) of the memory device integrated circuit, or an internally-generated voltage higher than the supply voltage, generated on-chip by a charge-pump voltage booster. The voltage partition is typically achieved using a resistive voltage partitioner made up of a certain number diode-connected P-channel and N-channel MOSFETs connected in series to each other (the specific number of these transistors depending on several parameters such as the initial voltage, the target biasing voltage, the MOSFETs&#39; threshold voltage and so on). 
   One such solution, in addition to being rather power consuming (a crowbar current flows through the voltage partitioner), has a very limited precision and does not guarantee that the storage element biasing voltage is sufficiently stable, depending on process parameters such as the MOSFETs&#39; threshold voltages, and there is no control on the voltage thus generated. 
   In particular, no control is operated on the threshold voltage of the biasing MOSFETs, which as known is subject to changes due to process statistical parameter variations and operating temperature. 
   This limited stability and predictability of the memory cell storage element biasing voltage, and thus of the drain voltage of the storage element, is very undesirable: if the drain voltage rises too much, soft-programming becomes significant, while too low a drain voltage may impair the operation of the sensing circuits that have to sense the current sunk by the storage element. 
   SUMMARY 
   In view of the foregoing, an embodiment of the present invention is a biasing structure for a memory cell, particularly but not limitatively of the electrically programmable and non-volatile type such as an EPROM, an EEPROM or a flash memory cell, adapted to ensure that the memory cell is biased in a stable, reliable condition when access thereto is needed. 
   According to an aspect of the present invention, such an embodiment includes a biasing structure, for setting an operating voltage at an accession electrode of a memory cell storage element, such as a storage transistor as it is typical in semiconductor, non-volatile memories. 
   In summary, the biasing structure comprises a biasing transistor coupled to the accession electrode and adapted to set the operating voltage based on a biasing voltage received at a control electrode of the biasing transistor, and a biasing voltage generator for generating the biasing voltage. 
   The biasing voltage generator includes a feedback voltage regulation structure adapted to track changes in a threshold voltage of the biasing transistor, so as to keep the operating voltage at the accession electrode of the memory cell storage element substantially stable against operating condition changes. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
     Features and advantages of the present invention will be made apparent by the following detailed description of an embodiment thereof, provided merely by way of non-limitative example, description that will be conducted making reference to the attached drawings, wherein: 
       FIG. 1  shows a semiconductor memory device in which a memory cell biasing structure according to an embodiment of the present invention can be advantageously exploited; 
       FIG. 2  is a partially schematic block and partially circuital diagram showing a biasing structure according to an embodiment of the present invention; 
       FIG. 3  is a detailed circuit diagram of the biasing structure of  FIG. 2 , according to one embodiment of the present invention; and 
       FIG. 4  is a diagram showing the results of simulations conducted on the biasing structure shown in  FIGS. 2 and 3  according to an embodiment of the invention, compared to a conventional biasing structure. 
   

   DETAILED DESCRIPTION 
   With reference to the drawings, in  FIG. 1  a semiconductor memory in which a biasing structure according to an embodiment of the present invention can be advantageously exploited is shown. The semiconductor memory is globally identified by  100  and is shown only schematically in terms of functional blocks, particularly those that are considered relevant to the understanding of the embodiment being described. The semiconductor memory  100  is for example a non-volatile, electrically-programmable memory such as a flash, and comprises a plurality of individually erasable sectors of memory cells or memory sectors, only one of which is shown in the drawing for simplicity and is identified by MS. Each memory sector includes a plurality of flash memory cells MC, schematically indicated in the drawing as dots, typically MOS transistors having a drain, a source, a control gate and a conductive-material (typically polysilicon) floating gate (albeit other memory cell structures are possible, for example memory cells formed by MOS transistors wherein instead of a polysilicon floating gate a silicon nitride charge-trapping layer is provided). The memory cells MC are conventionally arranged by rows and columns to form a two-dimensional array or matrix, and with each row and column there are respectively associated a respective word line WL and bit line BL. A row selector  105  and a column selector  110  are provided for selecting the matrix rows and columns, respectively, responsive to a row address (not shown in the drawing) and a column address CADD, part of an address code fed to the memory device  100 . 
   In order to make the memory device  100  fault tolerant to a certain extent, a redundancy scheme is implemented. In essence, the provision of the redundancy scheme calls for having a certain number of additional (redundant) storage resources in addition to those (normal storage resources) strictly necessary for achieving the target memory storage capacity; the redundant storage resources are exploited for functionally replacing the normal storage resources in case of failure thereof, for example due to manufacturing defects. In the example shown in the drawing, each memory sector includes a prescribed number of redundant memory cells RMC, each one connected to a respective one of a plurality of redundant bit lines RBL. In this way, when a memory cell MC in one of the (normal) bit lines BL is defective, or in general when one of the (normal) bit lines BL is affected by a defect, the defect can be overcome by functionally replacing the (normal but defective) bit line BL with one of the redundant bit lines RBL. In addition to, or instead of the redundant bit lines RBL, redundant word lines might as well be provided in each memory sector. In the example shown in the drawing, a whole sector of redundant memory cells or redundant memory sector RMS is also provided for (with associated row and column selectors, similarly to the normal memory sector MS), adapted to functionally replace an entire memory sector such as the memory sector MS in case of defects that cannot be repaired by exploiting the redundant bit lines RBL. 
   The implementation of a redundancy scheme such as the exemplary one depicted in the drawing requires a so-called redundancy circuitry that, effectively, is capable of storing the addresses of the defective storage resources, and of detecting when access (in read, write or erase) to the defective storage resources is requested, so as to automatically (and transparently to the outside) divert the access request towards the redundant storage resources chosen to functionally replace the defective ones. A known and rather typical way of realizing the redundancy circuitry calls for integrating, along with the other memory device circuits, a Content Addressable Memory (CAM), such as the CAM  115  shown schematically in  FIG. 1 . In particular, the CAM  115  should be non-volatile, so as to retain the information stored therein even in absence of power supply (the information concerning the defective storage resources, normally detected during the integrated circuit post-manufacturing test phase, should not get lost) and programmable, preferably electrically programmable. The CAM  115  comprises an array  120  of CAM memory cells CMC, arranged by rows and columns, with a CAM row selector  125  for selecting the CAM rows, and, associated with the CAM cell columns, CAM latches  130  for latching the content of the accessed CAM cells. The CAM cells content (latched in the CAM latches  130 ) is supplied to comparison circuits, typically XOR circuits  135 ,  140  that compare the CAM cells content with a current column address CADD and a current memory sector address SADD (a part of the memory address that is used for selecting one memory sector among the plurality of memory sectors); in case the current column address CADD coincides with (one of) the defective column address(es) stored in the CAM  115  (i.e., in case the address of a defective bit line that has been functionally replaced by a redundant bit line), an output of the XOR circuit  135  is asserted, and causes the redundant bit line RBL to be accessed instead of the defective bit line BL. Similarly, in case the current memory sector address SADD coincides with the defective memory sector address stored in the CAM  115 , an output of the XOR circuits  140  is asserted and causes the memory sector selector circuit  145  to select the redundant memory sector RMS instead of the defective memory sector. 
   In addition to storing the addresses of the defective storage resources for redundancy purposes, the CAM may be expediently exploited also for storing other data, such as memory configuration parameters for configuring memory device configurable structures, schematically shown as a block  150  (for example, the width of the memory word, in a memory design supporting both a byte-wide and a sixteen-bit wide memory word, or configuration data for trimming structures such as voltage partitioners and the like, and other possible configuration parameters). 
   Referring now to  FIG. 2 , the structure of the CAM  115  is shown in greater detail; in particular, this drawing shows the structure of a generic CAM cell CMC, of an associated CAM latch  130 , and a CAM cell biasing circuit  200  according to an embodiment of the present invention. 
   The generic CAM cell CMC includes a pair of storage units CMC 1 , CMC 2 , for example MOS transistors of the same type as those forming the memory cells MC and the redundant memory cells RMC, particularly (but not limitatively) floating-gate MOS transistors. The two MOS transistors CMC 1 , CMC 2  are intended to be programmed in such a way as to store mutually opposite states: for example, in order to store a logic state “1” in the CAM cell CMC, the MOS transistor CMC 1  stores a “1” (a condition conventionally corresponding to a low-threshold voltage or unprogrammed transistor state) and the MOS transistor CMC 2  stores a “0” (a condition conventionally corresponding to a relatively high-threshold voltage or programmed transistor state), and, viceversa, in order to store a logic state “0” in the CAM cell CMC, the MOS transistor CMC 1  stores a “0” and the MOS transistor CMC 2  stores a “1”. It is pointed out that this “differential” CAM cell structure is not at all limitative, and other structures are possible, in particular a structure of CAM cell including only one storage MOS transistor. 
   The two storage MOS transistors CMC 1  and CMC 2  have respective control gates connected to a same word line WLC of the CAM cell array  120  (associated with a CAM array row), and respective drain electrodes respectively connected to a first and a second bit lines BLC 1  and BLC 2  of the CAM cell array  120  (associated with a CAM array column). Source electrodes of the two storage MOS transistors CMC 1  and CMC 2  are connected to a reference voltage line (ground GND). 
   The first and second bit lines BLC 1  and BLC 2  are respectively connected to a first and a second inputs IL 1 , IL 2  of the associated CAM latch  130 . In series to each bit line BLC 1 , BLC 2 , a respective biasing transistor Q 1 , Q 2  is provided, having the main function of biasing the drain electrode of the associated CAM cell storage MOS transistor CMC 1 , CMC 2 . In particular, the biasing transistors Q 1  and Q 2  are N-channel MOSFETs having a source connected to the respective input IL 1 , IL 2 , thus to the respective bit line BLC 1 , BLC 2 , a drain connected to a respective terminal T 1 , T 2  of a structure essentially made up of a pair of (e.g., CMOS) inverters INV 1 , INV 2  cross-connected to each other, and a gate connected to a biasing voltage line Vb. An output COUT of the cross-connected inverter structure, connected to the output of the inverter INV 2  (but this is merely a matter of choice, being as well possible to connect the output to the output of the other inverter) forms the output of the CAM latch  130  and carries a logic state corresponding to the datum stored in the CAM cell CMC. 
   Similarly to the row selector  105  in the memory sector MS, in order to access the CAM cell CMC, the CAM row selector  125  biases the corresponding CAM word line WLC to a voltage that depends on the operation to be carried on the CAM  115 ; in particular, in order to program the CAM cell CMC, the potential of the CAM word line WLC is raised to a value sufficiently high (such as 9 V) to cause injection (or tunneling) of electrons into the floating gate, while in order to read the CAM cell content the potential of the CAM word line is brought to a lower value (e.g., 5 V or less) at least higher than the threshold voltage of the MOS transistors CMC 1 , CMC 2  when not programmed; when the CAM word line WLC is not selected, the potential thereof is for example kept at ground. 
   The biasing transistors Q 1  and Q 2  serve for biasing the drain electrode of the associated CAM cell storage MOS transistor CMC 1  and CMC 2  to a voltage which should be sufficiently low not to significantly stress the drain of the MOS transistors CMC 1  and CMC 2 ; stressing (from an electrical viewpoint) the drain of the MOS transistors CMC 1  and CMC 2  is probably the main cause of the spurious programming of the MOS transistors CMC 1  and CMC 2  even if such transistors are not submitted to the programming voltages (which are relatively high compared to the read voltages), a phenomenon called “soft programming”. The drain voltage of the MOS transistor CMC 1  and CMC 2  should also be sufficiently stable against operating condition changes, i.e. against changes in the temperature and in the integrated circuit supply voltage. 
   It is observed that the soft-programming problem also affects the memory cells MC in the memory sectors MS (as well as the redundant memory cells RMC in the memory normal and redundant memory sectors MS and RMS), and also in that case care needs to be used not to stress the drains of the memory cells&#39; floating gate MOS transistors. However, the storage MOS transistors CMC 1 , CMC 2  in the CAM array  120  may be more prone to the soft-programming problem because they may remain selected, and thus stressed, for relatively long times, possibly even for the whole time the memory device integrated circuit is kept on; this is for example the case of the CAM cells intended to store memory device configuration parameters, which belong to one or more CAM word lines that are kept selected for substantially all the time the memory device is powered, or CAM cells intended to store the address(es) of the defective memory sector(s); CAM cells that are intended to store addresses of defective storage resources within a given memory sector belong to CAM word lines that are kept selected as long as the corresponding memory sector is accessed (for these CAM cells, a shared CAM latch scheme can be exploited). 
   Conventionally, the biasing voltage that, through the biasing voltage line Vb, biases the transistors Q 1  and Q 2  is generated by means of a voltage partition from an initially higher voltage, which can be the supply voltage VDD of the memory device integrated circuit, or an internally-generated higher voltage generated by an on-chip charge-pump voltage booster, using a resistive voltage partitioner made up of a certain number diode-connected P-channel and N-channel MOSFETs connected in series to each other (the specific number depending on several parameters such as the initial voltage, the target biasing voltage, the MOSFETs&#39; threshold voltage and so on). 
   One such solution, in addition to being rather power consuming (a crowbar current flows through the voltage partitioner), has a very limited precision and does not guarantee that the biasing voltage is sufficiently stable, depending on process parameters such as the MOSFETs threshold voltages, and there is no control on the voltage thus generated. In particular, no control is exercised on the threshold voltage of the biasing MOSFETs Q 1  and Q 2 . 
   This limited stability and predictability of the biasing voltage, and thus of the drain voltage of the CAM storage MOS transistors CMC 1  and CMC 2 , is very undesirable: if the drain voltage of these transistors rises too much, soft-programming becomes significant, while too low a drain voltage impairs the operation of the CAM latch  130 , particularly the correct switching of the inverters INV 1 , INV 2 . 
     FIG. 2  shows schematically a bias voltage generator according to an embodiment of the present invention, adapted to overcome the above-mentioned problems. The bias voltage generator, identified globally by  200 , includes a circuit branch comprising a MOSFET Qx and, in series thereto, a current generator Ix, connected between the supply voltage VDD of the memory device integrated circuit and the ground GND. The MOSFET Qx is similar or, preferably, substantially identical to the bias MOSFETs Q 1  and Q 2  that control the drain voltage of the CAM cell storage transistors CMC 1 , CMC 2 . 
   The circuit branch, particularly the gate of the MOSFET Qx is controlled by a differential structure configured as a voltage follower: a differential amplifier  205 , of sufficiently high gain (e.g. an operational amplifier) has a non-inverting (“+”) input connected to a voltage generator Vdrain, generating a voltage Vdrain substantially equal to the target voltage for the drain of the CAM cell storage transistors CMC 1 , CMC 2 ; an inverting (“−”) input of the differential amplifier  205  is connected, through a feedback network (in the shown example, a simple short-circuit) to a source of the MOSFET Qx; an output O of the differential amplifier  205  is connected to and controls the MOSFET Qx, and to the biasing voltage line Vb. The differential amplifier  205  receives, as voltage supply, a voltage Vcp generated for example by a charge pump voltage booster  210  of the memory device (but this is not a limitation to the present invention). 
   Thanks to this circuit arrangement, and provided that the gain of the differential amplifier  205  (inserted in a negative feedback loop) is sufficiently high, the biasing voltage Vb that, through the biasing voltage line Vb, biases the gate of the biasing MOSFETs Q 1  and Q 2 , is such that a voltage Vx at a source node of the MOSFET Qx is:
 
Vx=Vdrain,
 
because the non-inverting input of the differential amplifier  205  behaves as a “virtual” ground and the circuit, by controlling the drive of the MOSFET Qx, and thus the voltage drop thereacross caused by the current Ix, tends to keep the differential amplifier inverting input “+” substantially at the same potential as the non-inverting input “−”.
 
   Since the MOSFET Qx is substantially identical to the bias MOSFETs Q 1  and Q 2  (in particular, it has substantially the same threshold voltage), which are driven by the same gate voltage Vb as the MOSFET Qx, the voltage at the source electrodes of the MOSFETs Q 1  and Q 2  is substantially identical to the voltage Vx at the drain of the MOSFET Qx, and thus to the target value Vdrain. 
   In this way, it is possible to precisely control the drain voltage of the CAM cell storage MOS transistors CMC 1 , CMC 2 , and that voltage is independent from the threshold voltage of the biasing MOSFETs Q 1 , Q 2 . Additionally, the drain voltage of the CAM cell storage MOS transistors CMC 1 , CMC 2  is stable against variations in the operating conditions, to the extent that the voltage Vdrain generated by the voltage generator Vdrain is stable. 
     FIG. 3  is a detailed circuit diagram of the biasing voltage generator shown schematically in  FIG. 2 , in one embodiment of the present invention. 
   In particular, the differential amplifier  205  includes one circuit branch in correspondence of the non-inverting input + and a plurality (three in the example) of circuit branches connected in parallel in correspondence of the inverting input −. The circuit branch in correspondence of the non-inverting input +comprises a series of a P-channel MOSFET Q 3  and an N-channel MOSFET Q 4 , wherein the MOSFET Q 3  is diode-connected and the MOSFET Q 4  is driven by the voltage Vdrain fed at the non-inverting input +. Each one of the three circuit branches corresponding to the inverting input − includes a series connection of a respective P-channel MOSFET Q 5 , Q 7 , Q 9 , in current-mirror configuration with the MOSFET Q 3 , and a respective N-channel MOSFET Q 6 , Q 8 , Q 10 , all driven by the voltage at the inverting input −, i.e. by the voltage Vx at the drain of the MOSFET Qx. 
   The MOSFETs in the four circuit branches of the differential amplifier are biased by a current generated by an N-channel MOSFET Q 11  with drain coupled to the source electrodes of the MOSFETs Q 4 , Q 6 , Q 8  and Q 10 , source connected to ground and gate biased by a bias voltage Vref, distributed through a reference voltage line Vref. 
   The reference voltage Vref is for example generated by means of a band-gap reference voltage generator  305  generating a stable band-gap reference voltage Vbg; the band-gap reference voltage Vbg is supplied to a non-inverting input of a differential amplifier  310  controlling a P-channel MOSFET Q 12  appended to the supply voltage VDD and in series to a resistor R connected to ground. The drain terminal of the MOSFET Q 12  is connected to the inverting input of the differential amplifier  310 . The output of the differential amplifier  310  also controls another P-channel MOSFET Q 13 , in a circuit branch parallel to that containing the MOSFET Q 12  and the resistor R, and wherein a diode-connected N-channel MOSFET Q 14  is connected in series to the MOSFET Q 13 . The voltage Vref corresponds to the voltage at the drain of the MOSFET Q 14 . 
   The voltage Vdrain that, in the schematic diagram of  FIG. 2 , is generated by the voltage generator Vdrain is generated in a way similar to the reference voltage Vref, although other voltage generation schemes are possible. 
   The current generator Ix appearing in the schematic diagram of  FIG. 2  is for example implemented by means of an N-channel MOSFET Q 15 , controlled by the reference voltage Vref. 
   In addition, circuit elements are provided in  FIG. 3 , which were not shown in the schematic diagram of  FIG. 2 , adapted to enable/disable the biasing voltage generator, responsive to an enable/disable signal DIS, controlled for example by a control circuit of the memory device. In particular, a P-channel MOSFET Q 16 , controlled by a logic complement of the signal DIS (and thus off when the biasing voltage generator is enabled), is connected in parallel to the MOSFET Q 3 ; an N-channel MOSFET Q 17 , Q 18 , Q 19  and Q 20 , controlled by logic complement of the signal DIS (and thus on when the biasing voltage generator is enabled), is inserted in each circuit branch of the differential amplifier, in series with the respective P-channel MOSFET Q 3 , Q 5 , Q 7 , Q 9 . An N-channel MOSFET Q 21 , controlled by the logic complement of the signal DIS (and thus on when the biasing voltage generator is enabled) is inserted in series with the MOSFET Q 11 . An N-channel MOSFET Q 22 , controlled by the signal DIS (and thus off when the biasing voltage generator is enabled) has drain connected to the output O of the differential amplifier  205 , and source connected to ground. Finally, an N-channel MOSFET Q 23 , controlled by the logic complement of the signal DIS (and thus on when the biasing voltage generator is enabled) is inserted in series with the MOSFET Qx. 
   It can be appreciated that the differential amplifier  205  has an unbalanced architecture, causing a higher fraction of the bias current, generated by the MOSFET Q 11 , to be deviated into the parallely-connected circuit branches corresponding to the inverting input −, while a lower current fraction flows in the branch corresponding to the non-inverting input +; this allows reducing the power-on time of the biasing voltage generator circuit, by shortening the settling time of the voltage Vb. 
   A capacitor C connected between the output O and the ground renders the voltage Vb stable during the switching of the CAM (change of CAM word line). 
   It is pointed out that the circuit structure depicted in  FIG. 3  is merely exemplary and not at all limitative. For example, it is sufficient that the differential amplifier  205  receives as a supply voltage a voltage higher than the target biasing voltage Vb. 
   In  FIG. 4  there are presented the results of simulations conducted on a biasing voltage generator structure of the type depicted in  FIG. 3 , compared to a conventional biasing voltage generator, consisting of a voltage partitioner. In particular, the variation in the biasing voltage Vb (in ordinate, unit: Volts) as a function of the operating temperature (in abscissa, unit: ° C.) in the two cases is presented. It can be appreciated that while the biasing voltage generator according to the described embodiment of the present invention ensures that the voltage Vb is stable and does not substantially vary (curve A), the biasing voltage generated by the conventional biasing voltage generator (curve B) greatly varies with the temperature, with all the negative consequences that have been outlined in the foregoing. 
   Thus, thanks to the biasing voltage generator according to an embodiment of the present invention, it is possible to generate a stable biasing voltage for controlling the transistors that bias the drain electrodes of the CAM cell storage transistors; the drain voltage of the CAM cell storage transistors is thus rendered stable and predictable in turn, and this reduces the problems of drain stress, and consequently the risk of soft-programming, that where instead encountered in the art. 
   It is pointed out that albeit described making reference to the biasing of CAM cell storage transistors, the invention is not limited to this case, being applicable in general whenever it is necessary to control a voltage corresponding to an electrode of a storage transistors, and in particular in the case of memory cells in a memory cell array, such as the memory cells MC within the memory sector MS. 
   Even more generally, the biasing structure can be exploited in connection with any kind of memory cell, either programmable or not. 
   Referring again to  FIGS. 1 and 2 , the memory  100 , which includes the biasing voltage generator  200 , may be incorporated in an electronic system such as a computer system. 
   Finally, it is underlined that although the present invention has been disclosed and described by way of some embodiments, it is apparent to those skilled in the art that several modifications to the described embodiments, as well as other embodiments of the present invention are possible without departing from the scope thereof.