Abstract:
A wordline decoder circuit and method of decoding a wordline input signal are provided. A first decoder receives multiple inputs to be evaluated. The first decoder includes a first precharge device for precharging a first node and a first discharge device to enable discharging the first node. A first clock signal enables the first discharge device. The first clock signal disables the precharge device. A clock delay circuit receives the first clock signal and generates a delayed clock signal. A second logic is coupled to the first decoder. The second logic provides a wordline output. The second logic wordline output is enabled responsive to the delayed clock signal and is disabled responsive to the first clock signal.

Description:
FIELD OF THE INVENTION 
     The present invention relates to clocked decoder circuits, and more particularly to, an improved wordline decoder circuit. 
     DESCRIPTION OF THE RELATED ART 
     Clocked NOR decoders are common in the art. For example, U.S. Pat. No. 5,737,270 discloses NOR decoders with locally generated clocks. FIG. 1 shows a precharged wordline decoder disclosed by U.S. Pat. No. 5,737,270. Precharged wordline decoder includes a first NOR decoder formed of multiple N-channel field effect transistors NFETs N 0 , N 1 , and NN connected between word OR top node (WORT) and word OR bottom node (WORB), respectively receiving address bits A 0 -AN. Precharged wordline decoder includes precharge P-channel field effect transistors PFETs P 1  and P 2 , respectively precharging WORT and WORB nodes, and a discharge N-channel field effect transistor NFETs ND 1 . In the NOR decoder, a first local clock CLKA is applied to discharge NFET ND 1  and to a clock delay circuit formed by inverters INV 1 , INV 2 . The clock delay circuit generates a locally-controlled delayed clock signal CLXB. A driver logic NAND circuit is formed by a driver NFET NDR, a precharge PFET P 3 , a discharge NFET ND 2 , clamping PFETs P 4  and P 5 , and an inverter INV 3 . 
     In FIG. 1, driver logic NAND circuit receives the locally-controlled delayed clock signal CLKB that is applied to the gates of precharge PFET P 3  and discharge NFET ND 2 . The gates of precharge PFETs P 1  and P 2  are connected to the gates of precharge PFET P 3  and discharge NFET ND 2  receiving delayed clock signal CLKB. The delayed clock signal CLKB disables the precharge PFETS P 1  and P 2  of the first NOR decoder. The gate of NFET NDR is driven by the output of NFETs N 0 , N 1 , through NN. The drain of driver NFET NDR at node labeled WLB is connected to the input of inverter INV 3  which provides the wordline output indicated at line WORDLINE. The clamping PFETs P 4  and P 5  respectively hold a high voltage level at nodes WLB and WORDLINE, preventing the decoder circuit from misdecoding due to a drop in the voltage level at the output nodes of the clamping devices. The driver logic NAND circuit receives the delayed clock signal CLKB for controlling the wordline driver devices, NFET NDR and inverter INV  3 . 
     Many existing decoder circuits have significant power requirements. Often required long hold times of existing decoder circuits are accommodated by delaying the data, thus adding area and impacting other aspects of performance. 
     Many existing decoder circuits have gating signals other than address bits, such as thread-select or enable to determine when the decoded signal is to be activated. In the common implementation of the clocked NOR decoder, an additional NOR device can be added. However an additional input will increase the NOR node loading and reduce performance slightly. In the case of a thread-select signal, the penalty is much greater. The thread-select function indicates the address decoding for the A-thread, is unique from the B-thread. Normally, the decodes would have to be duplicated using two copies of the illustrated decoder of FIG.  1 . One copy is active when the A-thread is selected, and the other being active when the B-thread is selected. The loading penalty on the address inputs is doubled by the addition of the thread-select function. In many designs, this additional loading is not tolerable due to the additional setup time it puts on the address inputs. 
     While the NOR decoder circuits of U.S. Pat. No. 5,737,270 provides improved performance over many existing decoder circuits, a need exists for an improved clocked NOR decoder circuit having improved power dissipation. It is desirable to provide improved hold time of NOR decoders with local clocks. It is desirable to provide an improved precharged wordline decoder with improved input loading characteristics. 
     SUMMARY OF THE INVENTION 
     A principal object of the present invention is to provide an improved wordline decoder circuit. Other objects are to provide such improved wordline decoder circuit enabling improved power dissipation; to provide such improved wordline decoder circuit enabling improved hold time performance and to provide such improved wordline decoder circuit substantially without negative effects and that overcomes many of the disadvantages of prior art arrangements. 
     In brief, a wordline decoder circuit and method of decoding a wordline input signal are provided. A first decoder receives multiple inputs to be evaluated. The first decoder includes a first precharge device for precharging a first node and a first discharge device to enable discharging the first node. A first clock signal enables the first discharge device. The first clock signal disables the precharge device. A clock delay circuit receives the first clock signal and generates a delayed clock signal. A second logic is coupled to the first decoder. The second logic provides a wordline output. The second logic wordline output is enabled responsive to the delayed clock signal and is disabled responsive to the first clock signal. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The present invention together with the above and other objects and advantages may best be understood from the following detailed description of the preferred embodiments of the invention illustrated in the drawings, wherein: 
     FIG. 1 is a schematic diagram of a prior art precharged wordline decoder with local clocks; 
     FIG. 2 is a schematic diagram of a precharged wordline decoder with a local clock in accordance with a preferred embodiment of the present invention; and 
     FIG. 3 is a schematic diagram of an alternative precharged wordline decoder with an inverted clock input in accordance with a preferred embodiment the present invention; 
     FIGS. 4A,  4 B,  4 C, and  4 D are charts with voltage relative to a vertical axis and time relative to a horizontal axis illustrating operation of the precharged wordline decoders of the preferred embodiment of FIGS. 2 and 3 for comparison with the prior art precharged wordline decoder of FIG. 1; 
     FIG. 5 is a chart with current relative to a vertical axis and time relative to a horizontal axis illustrating operation of the precharged wordline decoders of the preferred embodiment of FIGS. 2 and 3 for comparison with the prior art precharged wordline decoder of FIG. 1; 
     FIGS. 6A and 6B together provide a schematic diagram of an alternative precharged wordline decoder in accordance with preferred embodiments the present invention; and 
     FIG. 7 is a schematic diagram of another alternative precharged wordline decoder in accordance with preferred embodiments the present invention. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     Having reference now to the drawings, FIG. 2 illustrates a precharged wordline decoder circuit generally designated by the reference character  100  in accordance with a preferred embodiment of the present invention. Precharged wordline decoder circuit  100  is an embodiment of the invention using the same phase clock. 
     In accordance with features of the present invention, precharged wordline decoder circuit  100  provides improved hold time and less power dissipation as compared to the prior art circuit of FIG.  1 . With no penalty to the activation delay for the output WORDLINE, the precharged wordline decoder circuit  100  reduces power and shortens the hold time. Precharged wordline decoder  100  includes a first NOR decoder  102 , a clock delay circuit  104  and a second NAND wordline driver  106 . NOR decoder  102  includes multiple N-channel field effect transistors NFETs  108  connected between a word OR top (WORT) node and a word OR bottom (WORB) node respectively receiving address bits A 0 -AN. NOR decoder  102  includes a single precharged P-channel field effect transistor PFETs  110  connected to WORT node and an evaluate, discharge N-channel field effect transistor NFET  112  connected to the sources of the NFETs  108 . 
     Clock delay circuit  104  is formed by a pair of series connected inverters  114  receiving a clock CLKA. Clock delay circuit  104  generates a locally-controlled delayed clock signal CLKB at the output of the series connected inverters  114 . Driver logic NAND circuit  106  is formed by a driver NFET  116 , a driver inverter  118 , a precharged PFET  120 , a discharge NFET  122 , and a NFET  124 . Driver logic NAND circuit  106  includes a pair of clamping PFETs  126  and  128 . 
     In precharged wordline decoder  100 , the clock signal CLKA is applied to gates of precharge PFET  110  and discharge NFET  112  of NOR decoder  102 . The clock signal CLKA also is applied to the gates of precharge PFET  120  and discharge NFET  122  of the driver logic NAND circuit  106 . Driver logic NAND circuit receives the locally-controlled delayed clock signal CLKB applied to the gate input of NFET  124 . The gate of driver NFET  116  is driven by the output of the evaluate NFETs  108 . The drain of driver NFET  116  at node labeled WLB is connected to the input of inverter  118  which provides the wordline output indicated at line WORDLINE. The clamping PFETs  126  and  128  respectively hold a high voltage level at nodes WORT and WLB, preventing the decoder circuit from misdecoding due to a drop in the voltage level at the output nodes of the clamping devices. 
     Power reduction is accomplished by eliminating the precharge of WORB by precharge PFET P 2  of FIG. 1, and by changing the gate on precharge PFET  110  from CLKB of FIG. 1 to CLKA so that when CLKA goes high, PFET  110  is turned off. As a result, there is no DC current flow through PFET  110  and NFET  112  as the rising edge propagates from CLKA to CLKB. An improved hold time is accomplished by shortening the delay from CLKA falling to WORDLINE falling. A delay is required between CLKA rising and CLKB rising to give setup time for node WORT to evaluate or to unselect N− 1  out of N wordlines. However, that same delay is not required and is in fact a nuisance from CLKA falling to WORDLINE falling. This delay is minimized in precharged wordline decoder  100  by routing CLKA around the delay circuit  104  and directly into precharge PFET  120  and NFET  122  of the NAND decoder  106 . 
     Referring now to FIG. 3, there is shown an alternative precharged wordline decoder generally designated by the reference character  200  in accordance with a preferred embodiment the present invention. Precharged wordline decoder  200  includes an opposite phase of input clock CLKA of FIG.  2 . Precharged wordline decoder  200  similarly includes a first NOR decoder  202 , a clock delay circuit  204  and a second NAND wordline driver  206 . NOR decoder  202  includes multiple N-channel field effect transistors NFETs  208  connected between a word OR top (WORT) node and a word OR bottom (WORB) node respectively receiving address bits A 0 -AN. NOR decoder  202  includes a single precharged P-channel field effect transistor PFET  210  connected to WORT node and a discharge N-channel field effect transistor NFET  212 . 
     Clock delay circuit  204  is formed by a pair of series connected inverters  214  connected to a first input of a NOR gate  215 . A clock CLKA is applied to the input of the series connected inverters  214 . The clock CLKA is applied to a second input of the NOR gate  215  which provides the CLKB output. Driver logic NAND circuit  206  is formed by a driver NFET  216 , a driver inverter  218 , a precharged PFET  220 , and a discharge NFET  222 . Driver logic NAND circuit  206  similarly includes a pair of clamping PFETs  226  and  228 . In clock delay circuit  204 , a clock chopper on CLKB is implemented to reduce the falling edge delay. The CLKB output of NOR  215  provides the reduced falling edge delay responsive to the CLKA input. An inverted CLKA output of the first of the series connected inverters  214  is applied to the precharge PFET  210  and discharge NFET  212 . CLKB is applied to the gates of precharged PFET  220  and discharge NFET  222  of NAND driver circuit  206 . 
     FIGS. 4A,  4 B,  4 C,  4 C and  5  illustrate operation of the precharged wordline decoders  100  and  200  in comparison with the prior art precharged wordline decoder of FIG.  1 . FIG. 4A illustrates CLKA, CLKB generated by the prior art decoder of FIG. 1 together with wordline (WL) outputs of the prior art decoder of FIG. 1, and decoders  100  and  200  of the preferred embodiment. In FIG. 4A, the reduced hold times from the trailing edge of CLKA for the precharged wordline decoders  100  and  200  may be seen in comparison with the prior art precharged wordline decoder of FIG.  1 . FIG. 4B illustrates the operation of the prior art decoder of FIG.  1 . FIG. 4C illustrates the operation of the decoder  100  of FIG.  2 . FIG. 4D illustrates the operation of the decoder  200  of FIG. 3 with inverted CLKA. FIG. 5 illustrates respective power requirements for the operation of prior art decoder of FIG. 1, and decoders  100  and  200  of the preferred embodiment. In FIG. 5, operation of prior art decoder of FIG. 1 is indicated at a line IEV 1 . Operation of decoders  100  and  200  of the preferred embodiment are respectively shown at lines IEV 2  and IEV 3 . In FIG. 5, the reduced power requirements for the decoders  100  and  200  of the preferred embodiment may be appreciated as compared to the prior art decoder of FIG.  1 . 
     FIGS. 6A and 6B and FIG. 7 respectively illustrate alternative precharged wordline decoders generally designated by reference character  600  and  700  in accordance with preferred embodiments the present invention with improved input loading characteristics. 
     Referring to FIGS. 6A and 6B, precharged wordline decoder  600  includes a single NOR decoder circuit  102  arranged to be shared between two NAND wordline drivers  206 , for an A_SIDE and a B_SIDE thread select function. Precharged wordline decoder  600  utilizes a pair of clock delay circuits  602  and  604 . Each clock delay circuit  602 ,  604  is formed by a respective NAND gate  606 ,  608  connected in series with a respective inverter  610 ,  612 . CLKA is applied to a first input of NAND gates  606  and  608 . An A_SIDE input is applied to a second input of NAND gate  606 . An B_SIDE input is applied to a second input of NAND gate  608 . To select either or both decoders  106  for the A_SIDE and/or B_SIDE address inputs to the NOR decoder  102 , one or both of the A_SIDE and B_SIDE inputs to NAND gates  606  and  608  are selected. Since the address inputs A 0 -AN now support two outputs in the precharged wordline decoder  600 , the loading to the buffers that create these inputs are now ½ of the prior art arrangement. This allows for improvement of the address setup time characteristics for the precharged wordline decoder  600 . Further, since the delay performance of clock delay circuits  602  and  604  is set by how fast the WORT node discharges, sizing of the NAND gates  606 ,  608  and the address NOR devices  108  can be such that the CLIK to WORDLINE performance is not affected, while substantially retaining the setup time benefits. 
     Referring to FIG. 7, precharged wordline decoder  700  provides another form of the invention. Precharged wordline decoder  700  is formed of the NOR decoder circuit  102  and the NAND driver  106  of FIG.  3 . Precharged wordline decoder  700  includes a clock delay circuit  704  including a NAND gate  706  connected in series with an inverter  708 . In precharged wordline decoder  700 , an enable signal is introduced into NAND gate  706 , rather then being added to the NOR circuit  102  where the address inputs connect. Depending upon a particular application, precharged wordline decoder  700  can be a superior implementation. 
     While the present invention has been described with reference to the details of the embodiments of the invention shown in the drawing, these details are not intended to limit the scope of the invention as claimed in the appended claims.