Abstract:
A method and apparatus for reducing power consumption of a memory device. The method includes initiating a precharge operation. The precharge operation includes driving one or more bitlines to a precharge voltage. The method also includes identifying one or more defective wordlines and, during the precharge operation, driving the identified defective word lines to the precharge voltage.

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The invention generally relates to reducing the power consumption of memory devices. More specifically, the invention relates to reducing the power consumption of memory devices due to defects in the memory device. 
     2. Description of the Related Art 
     Many modern electronic devices contain digital memory (e.g., a dynamic random access memory, DRAM). Each memory may be used to store information for a digital device. Users of such electronic devices typically desire large amounts of memory in a small package. Where the electronic devices are portable (e.g., battery powered), users may also desire electronic devices which do not consume as much power and therefore have a longer battery life. Thus, manufacturers of electronic devices typically desire small, high density memories with low power consumption. 
     To meet the demand for small, high density memories, memory manufacturers typically create memory chips with the smallest available features (e.g., transistors and control lines) and with densely packed memory cells. However, as the size of features in a memory chip shrinks and as the memory density of a memory chip increases, small, uncontrollable errors in the manufacturing process may cause more defective memories at a high cost to the manufacturer. 
     An example of a possible defect in a memory device is a short (e.g., an unintended electrical connection) between a defective wordline and a bitline of a memory device. Wordlines and bitlines are lines in a memory device which are used to access a memory cell (e.g., at the junction of the wordline and bitline) in the memory device. Where a wordline and bitline are shorted, the memory cell located at the junction of the wordline and bitline may, in some cases, not be accessible, thereby resulting in a defective wordline and defective memory device. 
     To reduce the number of defective memory devices resulting from defective wordlines and/or bitlines, many manufacturers create memory devices with redundant wordlines and/or bitlines. Where, for example, the manufacturer detects a defective wordline, the memory device may use a redundant wordline instead of the defective wordline. When a memory device uses a redundant wordline instead of a defective wordline, the defective wordline may be referred to as a repaired wordline. 
     While repairing a defective wordline may prevent a memory device from losing data, the defective wordline may still remain shorted to a bitline. In some cases, where a defective wordline is shorted to a bitline, current may flow between the defective wordline and the bitline, thereby increasing the power consumption of the memory device. 
     As an example, when wordlines and bitlines are not being used to access memory cells, each wordline is deactivated and the bitlines are precharged in preparation for the next sensing operation. During deactivation, each wordline voltage may be lowered to a low voltage (e.g., the low wordline voltage, V NWLL ), thereby disconnecting each memory cell from the bitlines used to access the memory cell. The voltage of the bitlines when properly precharged is a voltage midway between the voltage corresponding to a bitline high logic level (V BLH ) and the voltage corresponding to a bitline low logic level (V BLL ). The midway voltage ((V BLH +V BLL )/2) may be referred to as the precharge voltage or bitline equalize voltage, V BLEQ . 
     However, where a wordline is defective (e.g., shorted to a bitline), during precharge, current may flow from the bitline being held at the precharge voltage (V BLEQ ) to the defective wordline being held at the low wordline voltage (V NWLL ). Where current flows between a defective wordline and a bitline, the power consumption of the memory device may increase. In some cases, because each defective wordline may be in a precharge state for an extended period of time (e.g., when the memory device is not being accessed but is in a standby state), and because each memory device may contain several defective wordlines, the power consumption of the memory device during precharging due to defective wordlines may be substantial, thereby decreasing the value of the memory device (e.g., by reducing the battery life of electronic devices which use the memory device). 
     Accordingly, what is needed are methods and apparatuses for reducing the power consumption of a memory device due to a defective wordline. 
     SUMMARY OF THE INVENTION 
     Embodiments of the present inventions generally provide a method and apparatus for reducing power consumption of a memory device. In one embodiment, the method includes initiating a precharge operation. The precharge operation includes driving one or more bitlines to a precharge voltage. The method also includes identifying one or more defective wordlines and, during the precharge operation, driving the identified defective wordlines to the precharge voltage. 
     One embodiment provides a memory device including one or more bitlines, one or more defective wordlines, and circuitry. The circuitry is configured to initiate a precharge operation, wherein the precharge operation comprises driving the one or more bitlines to a precharge voltage, identify one or more defective wordlines, and, during the precharge operation, drive the identified defective wordlines to the precharge voltage. 
     One embodiment provides a memory device including one or more bitlines, one or more defective wordlines, and means for controlling. The means for controlling is configured to initiate a precharge operation, wherein the precharge operation comprises driving the one or more bitlines to a precharge voltage, identify one or more defective wordlines, and during the precharge operation, drive the identified defective wordlines to the precharge voltage. 
     One embodiment provides a memory device including one or more bitlines, one or more defective wordlines, and means for controlling. The means for controlling is configured to initiate a precharge operation, wherein the precharge operation comprises driving the one or more bitlines to a precharge voltage, identify one or more defective wordlines, and during the precharge operation, electrically isolate the identified defective wordlines. 
     One embodiment of the invention provides a method for reducing power consumption of a memory device. The method includes detecting one or more defective wordlines in the memory device and storing address information identifying each of the one or more defective wordlines. The method also includes initiating a precharge operation, wherein the precharge operation comprises driving one or more bitlines to a precharge voltage, and during the precharge operation, identifying the one or more defective wordlines using the stored address information and driving the identified one or more defective wordlines to the precharge voltage. 
     One embodiment of the invention provides a memory device comprising a plurality of normal wordlines, one or more redundant wordlines, repair circuitry, precharge circuitry, bitline control circuitry, and repaired wordline deactivation circuitry. The one or more redundant wordlines are used to replace one or more defective normal wordlines. The repair circuitry is configured to store information identifying the one or more defective normal wordlines and the one or more redundant wordlines used to replace the one or more defective normal wordlines. The precharge circuitry is configured to initiate a precharge operation and the bitline control circuitry is configured to drive one or more bitlines to a precharge voltage during the precharge operation. The repaired wordline deactivation circuitry is configured to identify the one or more defective wordlines using the stored information and, during the precharge operation, drive the identified one or more defective wordlines to the precharge voltage. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       So that the manner in which the above recited features of the present invention can be understood in detail, a more particular description of the invention, briefly summarized above, may be had by reference to embodiments, some of which are illustrated in the appended drawings. It is to be noted, however, that the appended drawings illustrate only typical embodiments of this invention and are therefore not to be considered limiting of its scope, for the invention may admit to other equally effective embodiments. 
         FIG. 1  is a block diagram depicting a memory device according to one embodiment of the invention. 
         FIG. 2  is a block diagram depicting elements of a memory bank according to one embodiment of the invention. 
         FIG. 3  is a block diagram depicting a wordline decoder circuit according to one embodiment of the invention. 
         FIG. 4  is a flow diagram depicting a process for reducing the power consumption of a memory device due to a defective wordline according to one embodiment of the invention. 
         FIG. 5  is a block diagram depicting circuitry for applying a precharge voltage (V BLEQ ) to a repaired wordline according to one embodiment of the invention. 
         FIG. 6A  is a state diagram depicting activate and precharge states for a memory device according to one embodiment of the invention. 
         FIG. 6B  is a timing diagram depicting activate and precharge cycles of wordlines in a memory device according to one embodiment of the invention. 
     
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
     Embodiments of the invention generally provide a method and memory device for reducing power consumption in the memory device during precharge due to a defective wordline. In one embodiment, during precharge, the voltage for the defective wordline may be driven to a precharge voltage. The precharge voltage may also be applied to bitlines in the memory device. By applying the precharge voltage to the defective wordline and the bitlines, a leakage current (e.g., due to a short) between the defective wordline and bitlines may be reduced, thereby reducing the power consumption of the memory device during precharge. 
     While described below with respect to wordlines in a memory bank of a memory device, embodiments of the invention may be used in a memory device containing multiple memory banks. Embodiments may be utilized in memory devices with a segmented wordline architecture (e.g., where a main wordline is used to access a local wordline, also referred to as a hierarchical wordline architecture). Embodiments may also be utilized in memory devices with a stitched wordline architecture, for example, where a polysilicon wordline is electrically connected at multiple points (“stitched”) by stitches (electrical connections, sometimes referred to as straps) to a layer of low resistance metal. 
     Signal name used below are exemplary names, indicative of signal levels used to perform various functions in a given memory device. In some cases, the relative level of such signals may vary from device to device. Furthermore, the circuits and devices described below and depicted in the figures are merely exemplary of embodiments of the invention. As recognized by those of ordinary skill in the art, embodiments of the invention may be utilized with any memory device containing defective wordlines. 
     An Exemplary Memory Device 
       FIG. 1  is a block diagram depicting a memory device  100  according to one embodiment of the invention. The memory device  100  may include address inputs and command inputs. The address inputs may be received by an address buffer  104  and the command inputs may be receive by a command decoder  102 . The address inputs may be used by a wordline decoder  122  and column decoder  124  to access memory cells in a memory bank  120 . In some cases, multiple memory banks  120  may be accessed using a single wordline decoder  122  and column decoder  124 . 
     In one embodiment, the column decoder  120  may select bitlines  130  of the memory bank  120  to be accessed. Similarly, the wordline decoder  126  may select wordlines  128  to be accessed. In some cases, access may occur based on an address received by the memory device  100  from an external source. Optionally, the access may occur based on an address which is internally generated. Other circuitry such as sense amps, output buffers, data strobe circuits, etc. (not depicted) may also be used to access and output data from the memory bank  120 . 
     The memory bank  120  typically contains a plurality of memory cells. Each memory cell may be located at the intersection of a wordline  128  and a bitline and may be used to store a bit of information for the memory device  100 . In some cases, when a given row of memory cells in the memory bank  120  is accessed (e.g., by a read, write, or refresh), a wordline  128  in the memory bank  120  corresponding to a given address may be activated. In some cases, the activation may be initiated by an explicit command (ACT) issued to the memory device  100 . After the wordline  128  has been activated and the memory cells have been accessed, bitlines in the memory bank  120  may be precharged. In some cases, the precharge may also be initiated by an explicit command (PRE) issued to the memory device  100 . Activating and precharging are described in greater detail below. 
     When a memory address is activated, the wordline driver  126  for a wordline  128  corresponding to the accessed address may drive the wordline  128  to a high voltage (referred to as the wordline on voltage, V WLON ). When the wordline  128  is driven to V WLON , one or more access transistors located at the intersection of the wordline  128  and a bitline  130  may be activated (e.g., turned on), thereby allowing memory cells located at the intersection of the wordlines  128  and bitlines  130  to be accessed. 
     In one embodiment, after a wordline in the memory bank  120  has been activated, bitlines  128  in the memory bank  120  may be precharged. When the precharge is initiated, each wordline  128  in the memory bank  120  may be lowered to the low wordline voltage V NWLL , thereby electrically disconnecting the bitlines  130  from the memory cells in the memory bank  120 . As described above, when the bitlines  130  are disconnected from the memory cells, the bitlines  130  may be driven to a voltage (V BLEQ ) which is midway between the voltage corresponding to a bitline high logic level (V BLH ) and the voltage corresponding to a bitline low logic level (V BLL ), such as (V BLH +V BLL )/2). By precharging the bitlines  130  to V BLEQ , during a subsequent operation when the values stored in the memory cells are sensed using the bitlines  130 , a smaller voltage swing may be necessary to drive the bitlines  130  to the voltage corresponding to the stored logic value (e.g., V BLH  for a stored high logic level or V BLL  for a stored low logic level) and thereby sense the value stored in the memory cells. V BLEQ  may also be intermediate (or approximately intermediate) between the wordline off voltage V WLON  and the wordline off voltage V NWLL . 
     As mentioned above, in some cases, the memory device  100  may have a defect such as, for example, a short  140  between a wordline  128   1  and bitline  130   2 . To prevent such a defect from rendering a memory device  100  defective, the memory device  100  may contain circuitry used to repair defective wordlines. 
       FIG. 2  is a block diagram depicting circuitry used to repair a defective wordline according to one embodiment of the invention. In one embodiment, each memory bank  120  may be divided into separate blocks  206  with each block  206  containing a plurality of wordlines  128 . In some cases, the wordlines  128  in each block  206  may be accessed using a wordline decoder control circuit  202 . For example, the wordline decoder control circuit  202  may receive address data from the address buffer  104  and control information from the control circuit  110  which may be used to access the appropriate wordline. 
     In one embodiment of the invention, a defective wordline  128   1  in a block  206  may be detected by testing the memory device  100 . For example, a series of data values may be written to each address in the memory device  100  and then read from the memory device. A defective wordline  128   1  may be detected where the data read from memory device  100  fail to match the data values written. Testing methods are described below in greater detail. 
     As stated above, to prevent a defective wordline  128   1  from rendering a memory device  100  defective, the memory device  100  may contain circuitry used to replace the defective wordline  128   1  with another wordline (e.g., wordline  128   3 ) in the memory device  100 . A wordline used to replace a defective wordline  128   1  may be referred to as a redundant wordline  128   3 . Other wordlines which are not defective and are redundant wordlines (e.g., wordline  128   2 ) may be referred to as good wordlines. 
     When a defective wordline  128   1  is detected, fuses and repair circuitry  204  may be used to replace the defective wordline  128   1  with a redundant wordline  128   3 . For example, the fuses and repair circuitry  204  may record one or more addresses of the defective wordlines  128   1 , for example, by electronically programming one or more fuses. The fuses and repair circuitry  204  may also be used to record the location of one or more redundant wordlines  128   3  to be used instead of the defective wordline(s)  128   1 . 
     After the fuses and repair circuitry  204  have been programmed accordingly, the fuses and repair circuitry  204  may be used to detect an attempt to access the defective wordline  128   1 . For example, when the memory device  100  is powered on, the recorded address may be read from the fuses and repair circuitry  204  by the wordline control circuit  202  and/or other control circuits in the wordline decoder  122 . When the wordline decoder  122  receives a request to access a given address, the wordline decoder  122  may compare the requested address to one or more recorded addresses which correspond to defective wordlines  128   1 . 
     If the wordline decoder  122  detects an access to the recorded address corresponding to the defective wordline  128   1 , the redundant wordline  128   3  may be accessed instead. For example, the redundant wordline  128   3  may be driven to a wordline on voltage (V WLON ) while any and all defective wordlines (e.g., wordline  128   1 ) in a given block  126  may be driven to the wordline off voltage V NWLL , thereby accessing memory cells controlled by the redundant wordline  128   3  instead of the defective wordline  128   1 . By driving any and all defective wordlines in a given block  126  to the wordline off voltage V NWLL , additional capacitance that would be connected to the bitlines  130  (e.g., due to memory cells accessed by the defective wordlines) may be reduced (e.g., by disabling the access transistors for those memory cells), thereby increasing the signal margin for bitlines  130  in the block  126 . Also, by accessing the redundant wordline  128   3  instead of the defective wordline  128   1 , the memory device may properly access data located at the recorded address. Where a defective wordline  128   1  is properly replaced by a redundant wordline  128   3 , the defective wordline  128   1  may also be referred to as a repaired wordline  128   1  (or a defective and repaired wordline  128   1 ). 
     Thus, the defective wordline  128   1  may be repaired and the redundant wordline  128   3  may be used instead of the repaired wordline  128   1 , thereby preventing the memory device  100  from being defective. However, as described above, during precharge, current may flow from the repaired wordline  128   1 , which is held at V NWLL  to the bitline  130   2 , which is held at V BLEQ , through short  140 , thereby consuming power. 
     Limiting Power Consumption by a Repaired Wordline 
     According to one embodiment of the invention, power consumption in a defective and repaired wordline may be reduced or eliminated by using circuitry to change the repaired wordline voltage to V BLEQ  during precharge. In one embodiment of the invention, circuitry (referred to as repaired wordline deactivation control circuitry) may be used to identify the repaired wordline  128   1  and change the repaired wordline voltage to V BLEQ  during precharge. 
       FIG. 3  is a block diagram depicting a wordline decoder circuit  122  with repaired wordline deactivation control circuitry  306  according to one embodiment of the invention. Components in  FIG. 3  may be described with reference to  FIG. 4 , which illustrates operations  400  for reducing the power consumption of a memory device due to a defective wordline according to one embodiment of the invention. In other words, components illustrated in  FIG. 3  may be configured to perform operations  400  (e.g., independently or collectively) 
     The process  400  may begin at step  402  where each wordline  128  in the memory device  100  is tested to determine if there is a short between the wordline  128  and a bitline  130 . As described above, wordlines in the memory device may be tested by writing data to the memory device and reading data from the memory device. 
     At step  404 , if a wordline (e.g., wordline  128   1 ) is defective, address information identifying the defective wordline and a redundant wordline (e.g., wordline  128   3 ) to replace the defective wordline may be stored, for example, by blowing one or more fuses, for example, in the fuses and repair circuitry  204 . In some cases, the fuses may be electronically programmable fuses. Optionally, the fuses may be laser cut fuses or the address information may be stored in nonvolatile memory, such as, for example, a flash memory. 
     At step  406 , if an activate signal is received indicating that the wordline located at the stored address is being activated, the repaired wordline may be driven to the low wordline voltage V NWLL  and the redundant wordline may be driven to the wordline on voltage V WLON . In one embodiment, the wordline decoder control circuit  202  may use the information stored in the fuses and repair circuitry  204  to determine when the stored address is being accessed and to determine which wordline to activate. Thus, as described above, information located at the stored address may be successfully accessed by using the redundant wordline  128   3  instead of the repaired wordline  128   1 . 
     Then, at step  408 , when a precharge signal is received, for example, indicating that the memory bank  120  (or multiple memory banks) containing the defective wordline is being precharged, the stored address information may be used, for example, by the repaired wordline deactivation circuitry  306 , to drive the repaired wordline  128   1  to the precharge voltage, V BLEQ . As described above, by driving the repaired wordline voltage to V BLEQ , the repaired wordline  128   1  and the bitline  130   2  to which the repaired wordline  128   1  is shorted may have voltage levels which are equal or approximately equal. Because the voltage levels are equal or approximately equal, there may be no voltage difference between the repaired wordline  128   1  and the bitline  130   2 , and therefore no current between the repaired wordline  128   1  and the bitline  130   2 . Thus, a leakage current from the repaired wordline  128   1  to a bitline  130   2  may be reduced or eliminated, thereby reducing power consumption of the memory device  100  during precharge. 
       FIG. 5  is a block diagram depicting circuitry for applying a precharge voltage V BLEQ  to a repaired wordline  128   1  according to one embodiment of the invention. In one embodiment, the wordline drive  126  may receive a signal from the wordline decoder control circuit  202  during precharge. For example, the wordline decoder control circuit  202  may use the information recorded in the fuses and repair circuitry to determine whether a given wordline  128  located in the memory device  100  is a good wordline, a defective and/or repaired wordline, or a redundant wordline. 
     For example, if the control circuit  110  indicates that a precharge is being performed, the wordline decoder control circuit  202  may use the information provided by the fuses and repair circuitry  204  to determine which wordlines  128  are defective and repaired. If a wordline  128  is defective, the repaired wordline deactivation circuitry  306  may assert a signal to the wordline driver  126  indicating that the wordline voltage WL may be changed to the precharge voltage, V BLEQ . If, however, the fuses and repair circuitry  204  does not indicate that a given wordline  128  is defective, the wordline decoder control circuit  202  may assert a signal to the wordline driver  126  indicating that the wordline voltage WL may be changed to the wordline off voltage, V NWLL . 
     As described above, the wordline decoder control circuit  202  may also determine if an address being accessed during activation corresponds to a defective wordline. If the address being accessed does correspond to a defective wordline, the wordline decoder control circuit  202  may cause the wordline driver  126  to apply the wordline off voltage V NWLL  voltage to the defective wordline while the wordline decoder control circuit  202  may cause another wordline driver  126  to apply the wordline on voltage V WLON  to a redundant wordline (e.g., indicated by the fuses and repair circuitry  204 ), thereby accessing the redundant wordline instead of the defective wordline. 
     As described above, in some cases, the memory device  100  may perform a series of activations of one or more wordlines followed by a series of precharges.  FIG. 6A  is a state diagram depicting activate and precharge states for a memory device according to one embodiment of the invention. When an activate command is received by the memory device  100 , the memory device  100  may raise a signal (ACT) indicating that the activate command has been received and placing the memory device  100  in an activate state. 
     After the memory device  100  has been placed in the activate state, at some time later, a precharge command may be received, thereby causing a precharge signal (PRE) to be raised. Optionally, in some cases, the precharge command may be automatically issued (e.g., the PRE signal may be automatically raised) after the memory device  100  has been placed in the activate state (e.g., after the memory device  100  has been placed in the activate state for a given period of time). When the PRE signal is raised, the memory device may be placed into an idle state. Later, another activate command may place the memory device back in the activate state. 
       FIG. 6B  is a timing diagram depicting activate and precharge cycles of wordlines in a memory device according to one embodiment of the invention. As depicted, at time T 1 , a PRE signal may be asserted, indicating that one or more memory banks  120  are to be precharged. When the PRE signal is asserted, the wordline voltage for a defective and repaired wordline voltage may be changed to the precharge voltage, V BLEQ . Also, the wordline off voltage V NWLL  may be applied to the redundant wordline used to replace the repaired wordline. 
     Later, from time T 2  to T 3 , an ACT signal may be asserted, indicating that an address in the memory bank  120  is to be activated. When the ACT signal is received, the repaired wordline may be lowered to the wordline off voltage V NWLL , thereby deactivating any access transistors controlled by the defective wordline and allowing another wordline to be activated. Also, if the address being accessed during activation corresponds to the defective wordline, the redundant wordline may be accessed instead by driving the redundant wordline to the wordline on voltage V WLON , as depicted. 
     While embodiments are described above with respect to applying a precharge voltage V BLEQ  to a repaired wordline, in some cases, a repaired wordline may be electrically isolated (e.g., floated) during a precharge. Thus, in such cases, a circuitry and wiring to connect the repaired wordline to V BLEQ  may not be required. If the repaired wordline is electrically isolated during a precharge, no continuous current can flow between the repaired wordline and the bitline to which the repaired wordline is shorted. In one embodiment, one or more transistors may be used to electrically isolate the repaired wordline during the precharge. For example, a transistor may be placed between each wordline driver  126  and the power supply for V NWLL . During precharge, the transistor for each repaired wordline may be closed, thereby electrically isolating the repaired wordline from V NWLL . Optionally, one or more transistors may be placed between each wordline and wordline driver. During precharge, the one or more transistors connected to repaired wordlines may be closed, thereby electrically isolating the repaired wordlines. Optionally, each wordline driver may be modified, wherein a control signal issued to the wordline driver may be used to electrically isolate the wordline for the wordline driver. During precharge, the control signals issued to the wordline drivers for repaired wordlines may be used to electrically isolate the repaired wordlines. 
     In some cases, activate and precharge commands may be issued as separate commands to the memory device  100 , e.g., using the command inputs and/or address inputs. In other cases, the activate and precharge commands may be automatically issued by the memory device  100 , for instance, in response to another command received by the memory device  100  or in response to internal commands and/or circuitry of the memory device  100 . For example, the activate and precharge commands may be issued as a result of another command issued to the memory device  100 , such as a read command, write command, or refresh command. 
     In some cases, the refresh command may be an auto-refresh or CBR command. When an auto-refresh or CBR command is issued to the memory device, one or more memory banks  120  of the memory device  100  may be precharged. Also, an internal address register may be incremented. The memory address identified by the internal address register may be activated so that memory cells corresponding to the memory address may be refreshed. By issuing a group of auto-refresh or CBR commands to the memory device  100 , with each command refreshing a new address in the memory device  100 , the memory device  100  may be refreshed. 
     As another example of a refresh command, the refresh command may be a self-refresh command. When a self-refresh command is issued to the memory device, an internal address counter may be initialized and incremented. When the address counter is incremented, a different address identified by the address counter may be activated, thereby refreshing the identified address. In between activating each identified address, one or more memory banks  120  of the memory device may be precharged. The self-refresh command may automatically terminate after the entire memory device has been refreshed. 
     In one embodiment of the invention, a defective wordline may not be replaced with a redundant wordline, but address information identifying the defective wordline may be stored so that the defective wordline may be identified, thereby allowing the voltage of the defective wordline to be changed to the precharge voltage V BLEQ  during precharge. 
     While described above with respect to storing address information in fuses, where the address information identifies the defective wordline and/or a redundant wordline, in other embodiments, the identification and replacement of a defective wordline  128   1  with a redundant wordline  128   3  may be accomplished in another way, for example, without fuses which identify the defective wordline. In general, any means may be used to determine which wordlines are defective and/or repaired wordlines and which wordlines are redundant wordlines. 
     As described above, the memory device may be tested to determine which wordlines, if any, are defective. In some cases, the testing may occur during a manufacturing phase of the memory device, for instance, before or after the memory device has been packaged. Optionally, the testing may occur after the memory device has been installed in another electronic device and is placed in use. In some cases, the testing may occur before, or optionally after, a stress test of the memory device (referred to as a burn-in). 
     In some cases, the testing may be performed by another device (e.g., a tester or a processor in communication with the memory device). Optionally, the memory device may perform the test itself, for example, using built-in self test circuitry (BIST circuitry) within the memory device. In some cases, the self test may be performed, for example, in response to a command received by the memory device or when a flag is set in a mode register of the memory device. Also, in some cases, the self-test may be performed each time the memory device is initialized, for example, after the memory device is powered on or after the memory device is reset. 
     While described above with respect to a single memory bank accessed by a wordline decoder and a column decoder, as recognized by those skilled in the art, embodiments of the invention may be adapted for use with any acceptable memory device having memory in any acceptable configuration. For example, in some cases, the defective wordline and redundant wordline may be located in a single block in a single memory bank. Optionally, the defective wordline and the redundant wordline may be located in different blocks and/or different memory banks. 
     While described above with respect to replacing one defective wordline with a redundant wordline, embodiments of the invention may be utilized where any number of defective wordlines are replaced with any number of other, redundant wordlines. In some cases, a group of wordlines containing one or more defective wordlines may be replaced by a group of redundant wordlines. For example, as mentioned above, in some cases, embodiments of the invention may be utilized with a segmented wordline architecture containing one or more main wordlines and a plurality of local wordlines each accessed by a main wordline. Where a segmented wordline architecture is used, in some cases, a segment containing a defective wordline may be replaced with another segment, for example, by storing address information for the segments as previously described. 
     In some cases, where a segmented wordline architecture is used, the voltage for each main wordline may be re-driven by local wordline drivers (also referred to as re-drivers). Where local wordline drivers are utilized, each local wordline driver may be capable of driving a defective local wordline indicated by the fuses and repair circuitry  204  to V BLEQ  during a precharge, thereby reducing power consumption due to the defective local wordline. 
     While the foregoing is directed to embodiments of the present invention, other and further embodiments of the invention may be devised without departing from the basic scope thereof, and the scope thereof is determined by the claims that follow.