Abstract:
A fuse state detection circuit is comprised of a first fuse element, a second fuse element, and an output for carrying an output signal, the output signal represents a first logic state when the first fuse element is blown and the second fuse element is unblown and the output signal represents a second logic state when the first element is unblown and the second element is blown. The fuse state detection circuit produces an output signal whose state is recoverable from a negative triggering event and is capable of resolving itself to the correct state without the need for a reset pulse. Methods of using the fuse state detection circuit, such as a method of using fuse elements to control a setting within an electronic circuit, the improvement comprising using a pair of fuse elements to control a single setting, are also given.

Description:
BACKGROUND 
   The present invention relates generally to integrated circuits and more particularly to a circuit and/or method for detecting fuse states in an integrated circuit. 
   Fuse elements (such as laser fuses, anti-fuses, transistors, etc.) are used to establish a variety of settings within an integrated circuit. In a memory device, for example, fuse elements may be used to establish the part configuration (e.g., X 4 /X 8 /X 16 ) and/or various trimming settings (such as voltage levels, part timings, row and column repair/replacement, etc). One type of fuse that is utilized is referred to as a “laser fuse.” Typically, the memory device includes one or more strips of metal within a circuit that may be programmed, or “blown”, using a laser. The blown laser fuse causes a latch to be set to a specific state within the circuit. The state of the latch may then be used to set the operation of the memory device. Because a laser is used to program the laser fuses, the fuse setting process must be completed prior to memory device packaging. Accordingly, laser fuse settings cannot be modified after packaging is complete. 
   Another type of fuse element that is utilized is referred to as an “anti-fuse”. In an “unblown” (i.e., unprogrammed) condition, an anti-fuse functions as a capacitor presenting a very high resistance on the order of 10 Megohms to the circuit in which it is placed. In a “blown” (i.e., programmed) condition, the connections of the anti-fuse are shorted together (using a very high voltage, for example) providing a relatively low resistance (approximately 200 to 500 ohms) path through the anti-fuse. Because a laser is not required for programming, anti-fuses can be programmed after device packaging is completed. 
     FIG. 5  is a detailed view of a fuse state detection circuit  100  according to the prior art. The fuse state detection circuit  100  produces an output signal (X) having either a logic 1 (i.e., Vcc level) or a logic 0 (i.e., ground level). The output signal X is responsive to the state of the anti-fuse  106 . For example, the fuse state detection circuit  100  illustrated in  FIG. 5  produces an output signal X with logic 1 (i.e., Vcc) if anti-fuse  106  is “blown” and with logic 0 (i.e., GND) if anti-fuse  106  is “unblown.” 
   The operation of the prior art fuse state detection circuit  100  will now be discussed in more detail. The signals CGND, FA, BSELY_, MRG_, and DVC2F are used for programming the anti-fuse  106  and/or reading the state of anti-fuse  106 . When the memory device is operating under normal conditions, it is assumed that CGND=logic 0, FA=logic 0, BSELY_=logic 0, MRG_=logic 0, and DVC2F=logic 1. Under these conditions, the fuse state detection circuit  100  can be “simplified” as illustrated in  FIG. 6 . 
   The simplified circuit illustrated in  FIG. 6  is basically a simple latch with a reset p-channel transistor M 2  and anti-fuse  106 . The output of the latching circuit (i.e., signal X) is responsive to (and thus indicates) the state of anti-fuse  106 . As seen in  FIG. 6  when anti-fuse  106  is “blown”, anti-fuse  106  functions as a resistor and the voltage at node A is set at logic 0 (i.e., pulled to GND). Inverter  104  inverts the voltage present at node A such that when anti-fuse  106  is “blown,” the output signal X of fuse state detection circuit  100  is set to logic 1 (i.e., representing that anti-fuse  106  is blown). 
   When anti-fuse  106  is unblown, node A is floating because anti-fuse  106  acts as a capacitor, isolating node A from GND. In this case, the state of the Read Fuse signal (RDFUS_) is used to determine the logic state of output signal X. Initially, RDFUS_pulses “low,” turning on p-channel transistor M 2  and pulling node A to logic 1 (i.e., to Vcc). Accordingly inverter  104  inverts the voltage present at node A setting the logic state of output signal X to logic 0 (i.e., representing that anti-fuse  106  is unblown). When RDFUS_returns “high” (i.e., when the “low” pulse times out), p-channel transistor M 2  is turned off and feedback inverter  102  latches the logic state of output signal X at logic 0 (i.e., which continues to represent that anti-fuse  106  is unblown). 
   As is apparent from the above-description, when anti-fuse  106  is unblown the output state of fuse state detection circuit  100  is dependent upon the ability of the feedback inverter  102  to latch. Due to its weak driving signal, however, the latching ability of feedback inverter  102  may be easily overcome. Thus, the fuse state detection circuit  100  is susceptible to negative triggering events. A negative trigger event refers to any event that causes a node or point within a circuit to undesirably change states (e.g., to cause a node or point to change from a negative logic to a positive logic and/or to cause a node or point to change from a positive logic to negative logic). A negative triggering event may or may not cause the output of the fuse state detection circuit  100  to produce and erroneous signal X. Negative triggering events may be caused by voltage spikes due to signal coupling, a radiation particle strike, power bus drop, and/or a collection of positive or negative charge which can lead to circuit instability, among others. 
   If a negative triggering event occurs, the fuse state detection circuit  100  may produce an erroneous output signal X. For example, assume that anti-fuse  106  is unblown. As discussed above, node A is set to logic 1 and the output signal X set at logic 0. If a negative triggering event overcomes the latching ability of feedback inverter  102 , node A is forced to logic 0 and output signal X is forced to logic 1 erroneously representing that anti-fuse  106  is blown. If this were to happen, the device responsive to output signal X may not work properly. Fuse state detection circuit  100  requires that a new RDFUS_pulse be applied to reset the latch. 
   Although periodically pulsing RDFUS_to reset the latch  102  seems like an easy solution to the problem, such pulsing typically requires large amounts of current. More specifically, because some devices may include up to 10,000 anti-fuses, each with a fuse state detection circuit, a large amount of current is consumed each time the RDFUS_signal is pulsed. Accordingly, during normal operation RDFUS_is pulsed very infrequently to reduce the amount of current consumed by the device. 
   Thus, there exists a need for a fuse state detection circuit that resists negative triggering events, that resets itself without using a RDFUS_pulse should a negative triggering event cause the fuse state detection circuit to produce an erroneous output signal, and which overcomes other limitations inherent in prior art. 
   SUMMARY 
   One aspect of this disclosure relates to a fuse state detection circuit comprising a first fuse element, a second fuse element, and circuitry responsive to the first and second fuse elements for producing an output signal assuming a first logic state when the first fuse element is blown and the second fuse element is unblown and a second logic state when the first element is unblown and the second element is blown. 
   Another aspect of this disclosure relates to a fuse state detection circuit comprising a first fuse element, a second fuse element, and circuitry responsive to the first and second fuse elements so as to produce an output signal whose state is resistant to a negative triggering event. 
   Another aspect of this disclosure relates to a fuse state detection circuit comprising a first fuse element, a second fuse element, and circuitry responsive to the first and second fuse elements for producing an output signal capable of resolving itself to the correct state without the need for a reset pulse. 
   Another aspect of this disclosure relates to a method of using fuse elements to control a setting within an electronic circuit, the improvement comprising using a pair of fuse elements to control a single setting. 
   Another aspect of this disclosure relates to a method of operating a fuse state detection circuit comprising monitoring the state of a first fuse element, monitoring the state of a second fuse element, and producing an output signal that assumes a first logic state when the first fuse element is blown and the second fuse element is unblown and a second logic state when the first element is unblown and the second element is blown. 
   Another aspect of this disclosure relates to a method of operating a fuse state detection circuit comprising monitoring the state of a first fuse element, monitoring the state of a second fuse element, and producing an output signal that is responsive to the states of the first and the second fuse elements and whose state is resistant to a negative triggering event. 
   Another aspect of this disclosure relates to a method of operating a fuse state detection circuit comprising monitoring the state of a first fuse element, monitoring the state of a second fuse element, and producing an output signal that is responsive to the states of the first and the second fuse elements and resolves itself to the correct state without the need for a reset pulse. 
   Another aspect of this disclosure relates to a memory device comprising an array of memory cells, a plurality of peripheral devices for reading data out of and writing data into the array of memory cells, the peripheral devices comprising a fuse state detection circuit comprising a first fuse element, a second fuse element, and circuitry responsive to the first and second fuse elements for producing an output signal assuming a first logic state when the first fuse element is blown and the second fuse element is unblown and a second logic state when the first element is unblown and the second element is blown. 
   Another aspect of this disclosure relates to a memory device comprising an array of memory cells, a plurality of peripheral devices for reading data out of and writing data into the array of memory cells, the peripheral devices comprising a fuse state detection circuit comprising a first fuse element, a second fuse element, and circuitry responsive to the first and second fuse elements so as to produce an output signal whose state is resistant to a negative triggering event. 
   Another aspect of this disclosure relates to a memory device comprising an array of memory cells, a plurality of peripheral devices for reading data out of and writing data into the array of memory cells, the peripheral devices comprising a fuse state detection circuit comprising a first fuse element, a second fuse element, and circuitry responsive to the first and second fuse elements for producing an output signal capable of resolving itself to the correct state without the need for a reset pulse. 
   Another aspect of this disclosure relates to a system, comprising a processor, a memory device, and a bus for connecting the processor to the memory device, the memory device comprising an array of memory cells, a plurality of peripheral devices for reading data out of and writing data into the array of memory cells, the peripheral devices comprising a fuse state detection circuit, comprising a first fuse element, a second fuse element, and circuitry responsive to the first and second fuse elements for producing an output signal assuming a first logic state when the first fuse element is blown and the second fuse element is unblown and a second logic state when the first element is unblown and the second element is blown. 
   Another aspect of this disclosure relates to a system, comprising a processor, a memory device, and a bus for connecting the processor to the memory device, the memory device comprising an array of memory cells, a plurality of peripheral devices for reading data out of and writing data into the array of memory cells, the peripheral devices comprising a fuse state detection circuit comprising a first fuse element, a second fuse element, and circuitry responsive to the first and second fuse elements so as to produce an output signal whose state is resistant to a negative triggering event. 
   Another aspect of this disclosure relates to a system, comprising a processor, a memory device, and a bus for connecting the processor to the memory device, the memory device comprising an array of memory cells, a plurality of peripheral devices for reading data out of and writing data into the array of memory cells, the peripheral devices comprising a fuse state detection circuit comprising a first fuse element, a second fuse element, and circuitry responsive to the first and second fuse elements for producing an output signal capable of resolving itself to the correct state without the need for a reset pulse. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
     To enable the present invention to be easily understood and readily practiced, the present invention will now be described for purposes of illustration and not limitation, in connection with the following figures wherein: 
       FIG. 1  is a detailed schematic of a fuse state detection circuit according to one embodiment. 
       FIG. 2  is a simplified schematic the fuse state detection circuit of  FIG. 1  according to one embodiment. 
       FIG. 3  is a simplified block diagram of a processing system according to one embodiment. 
       FIG. 4  is a simplified diagram of a computing system according to one embodiment. 
       FIG. 5  is a detailed schematic of a fuse state detection circuit according to the prior art. 
       FIG. 6  is a simplified schematic the fuse state detection circuit of  FIG. 5  according to the prior art. 
   

   DETAILED DESCRIPTION 
   The detailed description sets forth specific embodiments which are described in sufficient detail to enable those skilled in the art to practice the present invention. It should be apparent to those skilled in the art that other embodiments may be utilized, and that logical, mechanical, and electrical changes may be made, while remaining within the scope of the present invention. The following detailed description is, therefore, not to be taken in a limiting sense, and the scope of the invention is defined only by the appended claims. 
     FIG. 1  is a detailed schematic of a fuse state detection circuit  10  according to one embodiment. Fuse state detection circuit  10  includes two fuse elements (e.g., anti-fuses AF- 1  and AF- 2 ), three inverters ( 14 ,  15 , and  16 ), and an NAND gate ( 18 ), among others. Briefly, fuse state detection circuit  10  uses the two fuse elements (AF- 1 , AF- 2 ) to produce an output signal X representing a programming state. Fuse state detection circuit  10  is capable of producing the output signal X without requiring a fuse sample pulse. In the current embodiment, polling of the fuse element state is unnecessary as the fuse state detection circuit  10  constantly monitors itself to determine the correct programming state. Fuse state detection circuit  10  consumes less power and provides improved stability for setting various device functions while maintaining all of the current functionality and testability requirements associated with fuse detection. 
   Some considerations for defining the functionality of the fuse state detection circuit  10  are as follows. Prior to any programming attempts, the fuse state detection circuit  10  is initialized. More specifically, the output signal X is forced to model a predetermined programming state (e.g., “unblown”) using the RDFUS_signal. Due to the use of multiple fuse elements (e.g., AF- 1 , AF- 2 ), the fuse elements require independent addressing (e.g., BSELX_, BSELY_, etc.) for reading the programming state or blowing the fuse elements. When a desired programming state is attempted, one of the two fuse elements (AF- 1 , AF- 2 ) must be blown. Both fuses should not be blown to set the programming state of fuse state detection circuit  10 . By leaving both fuses unblown, it is possible to achieve back-end or post-repair repair. In this situation, the initial RDFUS_pulse allows the output state to be defined as modeling an unblown fuse state, however, in this case the extra protection provided by this circuit implementation against various negative triggering events may be lost. An n-channel pass transistor may be added to provide a logical fuse read function while not creating a current fight. For example, n-channel pass transistor M 7  provides such a logical fuse read function. 
   By considering these cases, the output of fuse state detection circuit  10  is resistant to various negative triggering events (e.g., voltage spikes due to signal coupling, radiation particle strike, power bus drop, and/or a collection of positive or negative charge which can lead to circuit instability, among others). As discussed above, a negative triggering event refers to any event that causes a node or point within a circuit to undesirably change states (e.g., to cause a node or point to change from a negative logic to a positive logic and/or to cause a node or point to change from a positive logic to negative logic). A negative triggering event may or may not cause the output of the fuse state detection circuit  10  to produce and erroneous signal X. Additionally, under the assumption that one of the two fuse elements is always blown, any upset to the fuse state detection circuit  10  should allow it to resolve itself to the correct output state within a reasonable amount of time and without the need for a set/reset pulse. 
   Turning now to a detailed description of  FIG. 1 , fuse elements AF- 1  and AF- 2  (as discussed above) are anti-fuses in the current embodiment. A first terminal of anti-fuse AF- 1  is connected to the signal CGND, while a second terminal of anti-fuse AF- 1  is connected to the drain of transistor M 1 . The drain and gate terminals of transistor M 1  are connected to the second terminal of anti-fuse AF- 1  and a boosted voltage source (e.g., Vccp), respectively. The source terminal of transistor M 1  is connected to the drain of transistor M 2  and the source of transistor M 3 . The source and gate terminals of transistor M 2  are connected to the signal FA and the signal BSELX_, respectively. The drain terminal of transistor M 2  is connected to the source of transistor M 1  and the source of transistor M 3 . The gate and drain terminals of transistor M 3  are connected to the signal DVC2F and node A, respectively, whereas the source of transistor M 3  is connected to the source of transistor M 1  and the drain of transistor M 2 . 
   A first terminal of anti-fuse AF- 2  is connected to the signal CGND, while a second terminal of anti-fuse AF- 2  is connected to the drain of transistor M 4 . The drain and gate terminals of transistor M 4  are connected to the second terminal of anti-fuse AF- 2  and a boosted voltage source (e.g., Vccp), respectively. The source terminal of transistor M 4  is connected to the drain of transistor M 5  and the source of transistor M 6 . The source and gate terminals of transistor M 5  are connected to the signal FA and the signal BSELY_, respectively. The drain terminal of transistor M 5  is connected to the source of transistor M 4  and the source of transistor M 6 . The gate and drain terminals of transistor M 6  are connected to the signal DVC2F and the source terminal of transistor M 7 , respectively, whereas the source of transistor M 6  is connected to the source of transistor M 4  and the drain of transistor M 5 . The source, gate, and drain terminals of transistor M 7  are connected to the drain of transistor M 6 , the signal AFPROG_, and node B, respectively. 
   Inverter  14  is comprised of transistors M 16 , M 17 , and M 18 . The source, gate, and drain terminals of transistor M 16  are connected to a voltage source (e.g., Vcc), the output terminal of inverter  15 , and the source of transistor M 17 , respectively. The input terminal of inverter  15  is connected to node B. The source, gate, and drain terminals of transistor M 17  are connected to the drain of transistor M 16 , node A, and the output  17  of fuse state detection circuit  10 , respectively. The source, gate, and drain terminals of transistor M 18  are connected to output  17 , node A, and GND, respectively. 
   Inverter  16  is comprised of transistors M 8 , M 9 , and M 10 . The source, gate, and drain terminals of transistor M 8  are connected to a voltage source (e.g., Vcc), the signal MRG_and the source of transistor M 9 , respectively. The source, gate, and drain terminals of transistor M 9  are connected to the drain of transistor M 8 , node A, and node B, respectively. The source, gate, and drain terminals of transistor M 10  are connected to node B, node A, and GND, respectively. 
   NAND gate  18  is comprised of transistors M 11 , M 12 , M 13 , M 14 , and M 15 . The source, gate, and drain terminals of transistor M 11  are connected to a voltage source (e.g., Vcc), the signal MRG_and the sources of transistors M 12  and M 13 , respectively. The gate and drain terminals of transistor M 12  are connected to the signal RDFUS_and node A, respectively, whereas the source of transistor M 12  is connected to the drain of transistor M 11  and the source of transistor M 13 . The gate and drain terminals of transistor M 13  are connected to node B and node A, respectively, whereas the source of transistor M 13  is connected to the drain of transistor M 11  and the source of transistor M 12 . The source, gate, and drain terminal of transistor M 14  are connected to node A, node B, and the source of transistors M 15 , respectively. The source, gate, and drain terminals of transistor M 15  are connected to the drain of transistor M 14 , the signal RDFUS_, and GND, respectively. In the current embodiment; transistors M 1 -M 7 , M 10 , M 14 -M 15 , and M 18  are n-channel transistors, whereas transistors M 8 -M 9 , M 11 -M 13 , and M 16 -M 17  are p-channel transistors. 
   It should be noted that the specific embodiment of fuse state detection circuit  10  illustrated in  FIG. 1  is in no way intended to limit the scope of the present invention. For example, it should be apparent to one skilled in the art that the number and types of fuse elements, transistors, logic devices, etc. utilized by fuse state detection circuit  10  and the specific layout of said components as illustrated in the  FIG. 1  may be altered while remaining with scope of the present invention. 
   The operation of the fuse state detection circuit  10  will now be discussed in more detail. The signals CGND, FA, BSELX_, BSELY_, MRG_, and DVC2F are used for blowing (i.e., programming) anti-fuses AF- 1  and AF- 2  and/or reading the state of anti-fuses AF- 1  and AF- 2 . For example, anti-fuse AF- 1  is blown by setting CGND=logic 1, FA=logic 1, BSELX_=logic 0, BSELY_=logic 1, MRG_=logic 0, and DVC2F=logic 0; whereas anti-fuse AF- 2  is blown by setting CGND=logic 1, FA=logic 1, BSELX_=logic 1, BSELY_=logic 0, MRG_=logic 0, and DVC2F =logic 0. 
   In the current embodiment, “programming” refers to placing a fuse element into a “blown” state. For example, if the fuse element is an anti-fuse, programming may refer to effectively shorting the two terminal of the anti-fuse such that its resistance is significantly lowered. It should be apparent to one skilled in the art that fuse elements other than anti-fuses may be used while remaining within the scope of the present invention. Thus as a further example, if the fuse element is a laser fuse, programming may refer to cutting or severing one or more strips of metal that constitute the laser fuse. As an yet a further example, if the fuse element is a transistor or another re-programmable fuse device, programming may refer to applying a control signal to place the transistor or other re-programmable fuse device into a low resistance state. 
   When the memory device is operating under normal conditions, it is assumed that CGND=logic 0, FA=logic 0, BSELX_=logic 0, BSELY_=logic 0, MRG_=logic 0, and DVC2F=logic 1. Under these conditions, the fuse state detection circuit  10  can be “simplified” as illustrated in  FIG. 2 . 
   As discussed above, fuse state detection circuit  10  includes two anti-fuses (AF- 1  and AF- 2 ). The fuse state detection circuit  10  further includes an output  17  which carries an output signal X. The fuse state detection circuit  10  uses the two anti-fuses (AF- 1  and AF- 2 ) to produce the output signal X which represents a “blown” (i.e., programmed) or “unblown” (i.e., unprogrammed) state as would be seen, for example, by another circuit to which the output  17  of the fuse state detection circuit  10  is connected. In the current embodiment, programming anti-fuse AF- 1  is used to represent a “blown fuse” at output  17 , whereas programming anti-fuse AF- 2  is used to represent an “unblown fuse” at output  17 . Table 1 is a truth table according to the current embodiment. 
   
     
       
             
           
             
             
             
             
           
         
             
               TABLE 1 
             
           
           
             
                 
             
             
               Truth Table for Fuse state detection circuit 10 
             
           
        
         
             
                 
                 
                 
               Output 
             
             
                 
               AF-1 
               AF-2 
               Signal X 
             
             
                 
                 
             
             
                 
               Unblown 
               Unblown 
               Unblown 
             
             
                 
               Blown 
               Unblown 
               Blown 
             
             
                 
               Unblown 
               Blown 
               Unblown 
             
             
                 
               Blown 
               Blown 
               N/A 
             
             
                 
                 
             
           
        
       
     
   
   By using two fuse elements, the latch required by the prior art fuse state detection circuit  100  is eliminated, and thus, the possibility of a negative triggering event overcoming the latch is also eliminated. Additionally, the fuse state detection circuit  10  of the current embodiment is capable of correcting its output without the need of the RDFUS_pulse should a negative triggering event occur. 
   Returning briefly to  FIG. 1 , it should be apparent to one skilled in the art that transistors M 8  and M 11  act as current limiters. In the current embodiment, M 8  and M 11  are weak devices. In the case in which anti-fuse AF- 1  is blown, node A is pulled low (logic 0), output X is pulled high (logic 1) by inverter  14 , and node B is held high (logic 1) by the current through transistor M 8 . Because transistor M 8  is a weak device, its ability to recover, should a negative triggering event occur at node B (i.e., should node B erroneously switch from logic 0 to logic 1), may be inadequate. This could cause the output X to switch to an incorrect state and not be able to recover quickly enough. Thus in the current embodiment, inverter  15  and transistor M 16  are added to prevent output X from changing states when a negative triggering occurs at node B when AF- 1  is blown. More specifically, if a negative triggering event occurs which causes node B to temporarily flip states (i.e., change from logic 1 to logic 0), the output of inverter  15  also changes state (i.e., changes from logic 0 to logic 1) and deactivates transistor M 16 . When transistor M 16  is deactivated, the inherent capacitance of the output line  17  maintains output X at its high (i.e., logic 1) level. Accordingly, this is one example of the fuse state detection circuit&#39;s  10  resistance to a negative triggering event. Once transistor M 8  recovers from the negative triggering event, node B returns to logic 1, the output of inverter  15  returns to logic 0, and the transistor M 16  is activated to keep output X at logic 1. 
   In the case in which anti-fuse AF- 2  is blown, node B is strongly grounded through anti-fuse AF- 2 , so the recovery of node B is not as dependent upon the strength of transistor M 8  should a negative triggering event occur. 
   Preferably, only one of the anti-fuses (AF- 1  and AF- 2 ) is blown at a given time. Returning now to  FIG. 2 , if anti-fuse AF- 1  is blown, node A is pulled to logic 0 (e.g., GND) and inverter  14  causes output signal X to be set at logic 1 (which is the same output as the original circuit) If the anti-fuse AF- 2  is blown, node B is pulled to logic 0 and the output of NAND gate  18  is set at logic 1 (regardless of the logic level of signal RDFUS_). Inverter  14  thus causes the output signal X to be set at logic 0, which represents an unblown fuse in the original circuit. 
   If a negative triggering event-occurs to the fuse state detection circuit  10 , output signal X may change states for a short period of time. The fuse state detection circuit  10 , however, will eventually correct itself and output signal X will return to the correct logic state without needing an RDFUS_pulse. For example, node A is pulled to logic 0 when anti-fuse AF- 1  is blown as discussed above. If a triggering event forces node A to a logic 1 state, node A will quickly be pulled back to GND (i.e., to logic 0) through blown anti-fuse AF- 1 . Similarly, node A is pulled to logic 1 when anti-fuse AF- 2  is blown as discussed above. If a triggering event forces node A to a logic 0 state, node A will quickly be pulled back to Vcc (i.e., to logic 1) by the output of NAND gate  18 . Thus, regardless of whether anti-fuse AF-1 is blown (i.e., representing a blown fuse) or anti-fuse AF- 2  is blown (i.e., representing an unblown fuse), the fuse state detection circuit  10  is capable of resetting itself from a negative triggering event without needing a RDFUS_pulse. 
     FIG. 3  is a simplified block diagram of a processing system  1  comprised of a microprocessor, micro-controller, ASIC, etc.  2  in communication with a memory device  4 . The microprocessor is capable of performing various computing functions, such as executing software functions to perform specific calculations and/or data processing tasks. The processor  2  is capable of performing a plurality of functions based on information and data stored in the memory device  4 . 
   The memory device  4  may, for example, be a dynamic random access memory (DRAM) such as a static dynamic random access memory (SDRAM), a pseudo-static random access memory (PSRAM), and a low-power, extended-refresh dynamic random access memory (LPDRAM), among others. As shown in  FIG. 3 , various signals are shared between the processor  2  and the memory device  4  via a bus  20 . Bus  20  may include, for example, an address bus  22 , data bus  24 , and control bus  26 , among others. For example, cell address signals (ADDRESS), row address strobes (RAS), column address strobes (CAS), data (DQ) signals, write enable (WE) signals, timing (CLOCK) signals, etc. may be shared between the processor  2  and the memory device  4  via bus  20 . It should be apparent to one skilled in the art that the illustrated buses and mentioned signals are for exemplary purposes only and not intended to limit the present invention. 
   The memory device  4  is comprised of a main memory array  9  together with peripheral circuitry to enable data to be read into and out of the memory array  9 . The main memory array  9  may be further divided into a number of sub-arrays (not shown). Those of ordinary skill in the art will recognize that peripheral circuitry may include a memory controller  5 , an address decoder  6 , a column decoder  7 , and a row decoder  8 , among other components for writing information into and reading information out from main memory array  9 . One skilled in the art will recognize that the detailed description of these peripheral circuits is unnecessary as they do form a feature of the present invention. The peripheral circuitry may also include fuse circuits  11 . The fuse circuits  11  may be used, for example, to establish the memory device  4  configuration (e.g., X 4 /X 8 /X 16 ) and/or various trimming settings (such as voltage levels, part timings, row and column repair/replacement, etc) within the memory device  4 . In the current embodiment, the fuse circuits  11  include one or more fuse state detection circuits  10  as discussed above in conjunction with  FIGS. 1 and 2 . Those of ordinary skill in the art will also recognize that other peripheral circuitry may be included which are not disclosed in detail, as they do not form a feature of the present invention. 
     FIG. 4  is a block diagram depicting a computing system  30  in which the processing system  1  illustrated in  FIG. 3  may be used. The computing system  30  may include one or more input devices  32  (e.g., keyboard, mouse, microphone, bar code reader, RFID reader, etc.) connected to the processing system  1  to allow a user to manually input data, instructions, etc., to operate the processing system  1 . One or more output devices  34  (e.g., printers, video terminals, video display units, etc.) connected to the processing system  1  may also be provided as part of the system  30  to display or otherwise output data generated by the processing system  1 . The system  30  may also include one or more data storage devices  36  (i.e., CD-ROM, disk drive, tape drive, ZIP drive, etc.) connected to the processing system  1 . The data storage devices  36  are operable to store various software and data sets for use by processing system  1 . Computing system  30  may also include mixed input/output devices (not shown) such as modems, network interface cards, and touch screens (among others) while remaining within the scope of the present invention. 
   It should be recognized that the above-described embodiments of the invention are intended to be illustrative only. Those skilled in the art may devise numerous alternative embodiments without departing from the scope of the following claims. For example, the scope of the present invention may extend to other types of fuse elements and is not intended to be limited to anti-fuses. More specifically, laser fuses, re-settable fuses (such as transistors), etc. may be used with or in the place of anti-fuses while remaining within the scope of the present invention.