A memory array MA0 is divided into four sub memory arrays by sense amplifier strips. word drivers belonging to each sub memory array are connected to a corresponding segment boosted signal line. A fuse is connected to each segment boosted signal line. By blowing out a fuse, the sub memory array corresponding to the blown out fuse is no longer used. The sub memory array that is no longer used is exchanged with a spare sub memory array of a spare memory array.
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18. A semiconductor memory device comprising a word driver for activating a word line, wherein said word driver comprises
a first p channel mos transistor having a gate electrode supplied with a row decode signal and a source electrode supplied with a boosted decode signal, and an n channel mos transistor having a gate electrode supplied with a row decode signal identical to said row decode signal, and connected in series with said first p channel mos transistor.
16. A semiconductor memory device comprising a word line activation means for activating a word line, wherein said word line activation means comprises
a first, first conductivity type transistor having a control electrode applied with a row decode signal, and a first electrode supplied with a boosted decode signal, and a first second conductivity type transistor having a control electrode supplied with a row decode signal identical to said row decoder decode signal, and connected in series with said first first conductivity type transistor.
32. A semiconductor memory device comprising:
a submemory array having a plurality of memory cells connected to a plurality of word lines; a global boosted line to which a boosted potential higher than a power supply potential is supplied; a segment boosted line provided corresponding to said submemory array; word line select means for selecting any of said plurality of word lines; word line activation means responsive to an output from said word line select means for providing the potential of said segment boosted line to a selected one of said plurality of word lines to activate the same; and switching means connected between said segment boosted line and said global boosted line for selecting an electrical connection of said segment boosted line with said global boosted line, wherein said switching means is conductive in an active cycle of said submemory array, and is non-conductive in a standby cycle of said submemory array.
1. A semiconductor memory device comprising:
a submemory array having a plurality of memory cells connected to a plurality of word lines, a global boosted line to which a boosted potential higher than a power supply potential is supplied, a segment boosted line provided corresponding to said submemory array, word line select means for selecting any of said plurality of word lines, word line activation means responsive to an output from said word line select means for providing the potential of said segment boosted line to a selected one of said plurality of word lines to activate the same, first switching means connected between said segment boosted line and said global boosted line for selecting an electrical connection of said segment boosted line with said global boosted line, and potential maintaining means for maintaining the potential of said segment boosted line at a potential between ground potential and said boosted potential provided to said global boosted line.
38. A semiconductor memory device comprising:
a memory array including a plurality of submemory arrays, each submemory array having a plurality of memory cells arranged in rows and columns and a plurality of word lines arranged in the corresponding rows; a plurality of segment boosted lines, each provided corresponding to each submemory array, respectively, to which a boosted potential higher than a power supply potential is selectively applied, a plurality of row decoders, each provided corresponding to each submemory array, respectively, and for selecting any of said plurality of word lines arranged in the corresponding submemory array, and a plurality of word driver groups each provided corresponding to each submemory array, respectively, each word driver group including a plurality of word drivers, each word driver provided corresponding to each word line of the corresponding sub memory submemory array and responsive to an output of the corresponding row decoder for applying the boosted potential of the corresponding segment boosted line to the corresponding word line of the corresponding submemory array.
5. A semiconductor memory device comprising:
a memory submemory array having a plurality of submemory memory cells connected to a plurality of word lines, a global boosted line to which a boosted potential higher than a power supply potential is supplied, a segment boosted line provided corresponding to said submemory array, a row decoder for selecting any of said plurality of word lines, a plurality of word drivers, each connected between said segment boosted line and each of said plurality of word lines, wherein each of said plurality of word drivers comprises a first conductivity type transistor connected between said segment boosted line and a word line corresponding to each of said plurality of word drivers, and having a control electrode supplied with an output of said row decoder, a second conductivity type transistor having a first electrode connected to said corresponding word line, a second electrode supplied with ground potential, and a control electrode supplied with an output of said row decode, a switching transistor connected between said segment boosted line and said global boosted line for being turned on/off according to a control signal applied to the control electrode thereof, control signal generating means for generating a control signal applied to the control electrode of said switching transistor, and potential maintaining means for maintaining the potential of said segment boosted line at a potential between ground potential and said boosted potential applied to said global boosted line.
20. A semiconductor memory device comprising a submemory array having a plurality of memory cells connected to a plurality of word lines, wherein said submemory array comprises a plurality of memory cell groups, each of said plurality of memory cell groups including a predetermined number of said plurality of word lines
a plurality of segment boosted lines each provided corresponding to each memory cell group, to which a boosted potential high than a power supply potential is selectively applied, word line select means for selecting any of said plurality of word lines, and word line activation means responsive to an output of said word line select means for providing the potential of the segment boosted line to which said boosted potential is selectively applied to any of said predetermined number of word lines included in each memory cell group for activating the same, said word line activation means including a plurality of word drivers provided corresponding to said plurality of word lines respectively and said plurality of segment boosted lines, each of said word drivers including (a) a p channel mos transistor coupled between a corresponding one of said plurality of segment boosted lines and a corresponding one of said plurality of word lines, (b) a first n channel mos transistor coupled between the corresponding one of said plurality of word lines and a low potential, and having a gate coupled to a gate of said p channel mos transistor, and (c) a second n channel mos transistor coupled between the corresponding one of said plurality of word lines and the low potential. 34. A semiconductor memory device comprising:
a submemory array having a plurality of memory cells connected to a plurality of word lines; a global boosted line to which a boosted potential higher than a power supply potential is supplied; a segment boosted line provided corresponding to said submemory array; word line select means for selecting any of said plurality of word lines; a plurality of word drivers responsive to an output from said word line select means for providing the potential of said segment boosted line to a selected one of said plurality of word lines to activate the same, wherein each of said plurality of word drivers is connected between said segment boosted line and each of said plurality of word lines, and wherein each of said plurality of word drivers comprises, a first conductivity type transistor connected between said segment boosted line and a word line corresponding to each of said plurality of word drivers, and having a control electrode supplied with an output of said word line selecting select means, and a second conductivity type transistor having a first electrode connected to said corresponding word line, a second electrode supplied with ground potential, and a control electrode supplied with an output of said word line selecting select means; and a switching means connected between said segment boosted line and said global boosted line for selecting an electrical connection of said segment boosted line with said global boosted line, wherein said switching means is conductive in an active cycle of said submemory array, and is non-conductive in a standby cycle of said submemory array.
35. A semiconductor memory device comprising:
a submemory array having a plurality of memory cells connected to a plurality of word lines; a global boosted line to which a boosted potential higher than a power supply potential is supplied; a segment boosted line provided corresponding to said submemory array; word line select means for selecting any of said plurality of word lines; a plurality of CMOS word drivers responsive to an output from said word line select means for providing the potential of said segment boosted line to a selected one of said plurality of word lines to activate the same, wherein each of said plurality of CMOS word drivers is connected between said segment boosted line and each of said plurality of word lines, and wherein each of said plurality of CMOS word drivers comprises, a first conductivity type transistor connected between said segment boosted line and a word line corresponding to each of said plurality of word drivers, and having a control electrode supplied with an output of said word line selecting means, and a second conductivity type transistor having a first electrode connected to said corresponding word line, a second electrode supplied with ground potential, and a control electrode supplied with an output of said word line selecting means; switching means connected between said segment boosted line and said global boosted line for selecting an electrical connection of said segment boosted line with said global boosted line, wherein said switching means is conductive in an active cycle of said submemory array, and is non-conductive is in a standby cycle of said submemory array; and potential maintaining means for maintaining the potential of said segment boosted line at a potential between ground potential and said boosted potential provided to said global boosted line.
31. A semiconductor memory device comprising:
a submemory array having a plurality of memory cells connected to a plurality of word lines, wherein said submemory comprises a plurality of memory cell groups, each of said plurality of memory cell groups including a predetermined number of said plurality of word lines, a spare memory array having a plurality of spare memory cells connected to a plurality of spare word lines, wherein said spare memory array comprises a spare memory cell group, said spare memory cell group including a predetermined number of said plurality of spare word lines, a global boosted line to which a boosted potential higher than a power supply potential is supplied, a plurality of segment boosted lines each provided corresponding to each of said plurality of memory cell groups, a spare segment boosted line provided corresponding to said spare memory cell group, a row decoder for selecting any of said plurality of word lines, a spare row decoder for selecting any of said plurality of spare word lines, a plurality of first switching transistors, each connected between each of said plurality of segment boosted lines and said global boosted line, for selecting an electrical connection of each of said plurality of segment boosted lines with said global boosted line, a second switching transistor connected between said spare segment boosted line and said global boosted line for selecting an electrical connection of said spare segment boosted line with said global boosted line, a plurality of word drivers, each connected between each of said plurality of segment boosted lines and said plurality of word lines for transmitting the potential of a segment boosted line connected to said global boosted line according to an output of said row decoder to any of said predetermined number of word lines included in each corresponding memory cell group, a plurality of spare word drivers, each connected between said spare segment boosted line and each of said plurality of spare word lines, for transmitting the potential of a spare segment boosted line connected to said global boosted line according to an output of said spare row decoder to any of said predetermined number of spare word lines included in a corresponding spare memory cell group, and a plurality of fuses, each provided between said global boosted line and each of said plurality of segment boosted lines, connected in series with each of said plurality of first switching transistors.
30. A semiconductor memory device comprising:
a submemory array having a plurality of memory cells connected to a plurality of word lines, wherein said submemory array comprises a plurality of memory cell groups, each of said plurality of memory cell groups including a predetermined number of said plurality of word lines, a spare memory array having a plurality of spare memory cells connected to a plurality of spare word lines, wherein said spare memory array comprises a spare memory cell group, said spare memory cell group including a predetermined number of said plurality of spare word lines, a global boosted line to which a boosted potential higher than a power supply potential is supplied, a plurality of segment boosted lines each provided corresponding to each of said plurality of memory cell groups, a spare segment boosted line provided corresponding to said spare memory cell group, a row decode for selecting any of said plurality of word lines, a spare row decoder for selecting any of said plurality of spare word lines, a plurality of first switching transistors, each connected between each of said plurality of segment boosted lines and said global boosted line, for selecting an electrical connection of each of said plurality of segment boosted lines with said global boosted line, a second switching transistor connected between said spare segment boosted line and said global boosted line for selecting an electrical connection of said spare segment boosted line with said global boosted line, a plurality of word drivers, each connected between each of said plurality of segment boosted lines and said plurality of word lines for transmitting the potential of a segment boosted line connected to said global boosted line according to an output of said row decoder to any of said predetermined number of word lines included in each memory cell group, a plurality of spare word drivers, each connected between said spare segment boosted line and each of said plurality of spare word lines, for transmitting the potential of spare word lines, for transmitting the potential of a spare segment boosted line connected to said global boosted line according to an output of said spare row decoder to any of said predetermined number of spare word lines included in a corresponding spare memory cell group, and a plurality of fuses provided corresponding to each of said plurality of first switching transistors to be programmed to always turn off each of said plurality of first switching transistors.
2. The semiconductor memory device according to
wherein said potential maintaining means comprises resistor means connected parallel to said first switching means, and second switching means connected in series with said resistor means for selecting an electrical connection of said segment boosted line with said global boosted line via said resistance means according to a detection output of said detection means.
3. The semiconductor memory device according to
a node to which a potential is provided between boosted potential supplied to said global boosted line and ground potential, and diode means connected between said node and said segment boosted line.
4. The semiconductor memory device according to
6. The semiconductor memory device according to
said first conductivity type transistor included in each of said plurality of word drivers comprises a first p channel mos transistor having a gate electrode supplied with an output of said row decoder, said second conductivity type transistor included in each of said plurality of word drivers comprises an n channel mos transistor having a gate electrode supplied with an output of said row decoder, said switching transistor comprises a second p channel mos transistor having a gate electrode supplied with a control signal generated by said control signal generation means, and said potential maintaining means comprises a series element including a resistor and a fuse, connected between said global boosted line and said segment boosted line.
7. The semiconductor memory device according to
8. The semiconductor memory device according to
9. The semiconductor memory device according to
said first conductivity type transistor included in each of said plurality of word drivers comprises a first p channel mos transistor having a gate electrode supplied with an output of said row decoder, said second conductivity type transistor included in each of said plurality of word drivers comprises an n channel mos transistor having a gate electrode supplied with an output of said row decoder, said switching transistor comprises a second p channel mos transistor having a gate electrode supplied with a control signal generated by said control signal generation means, said potential maintaining means comprises: a power supply potential node to which a power supply potential is supplied, a series element including a diode element and a fuse, and connected between said power supply potential node and said segment boosted line SL0). 10. The semiconductor memory device according to
11. The semiconductor memory device according to
12. The semiconductor memory device according to
said first conductivity type transistor included in each of said plurality of word drivers comprises a first p channel mos transistor having a gate electrode supplied with an output of said row decoder, said second conductivity type transistor included in each of said plurality of word drivers comprises an n channel mos transistor having a gate electrode supplied with an output of said row decoder, said switching transistor comprises a second p channel mos transistor having a gate electrode supplied with a control signal generated by said control signal generation means, said potential maintaining means comprises a first series element including a resistor and a fuse, and connected between said global boosted line and said segment boosted line, a power supply potential node to which a power supply potential is supplied, and a second series element including a diode element and a fuse, and connected between said power supply potential node and said segment boosted line. 13. The semiconductor memory device according to
14. The semiconductor memory device according to
15. The semiconductor memory device according to
wherein said first conductivity type transistor includes in each of said plurality of word drivers comprises a first p channel mos transistor having a gate electrode supplied with an output of said row decoder, wherein said second conductivity type transistor included in each of said plurality of word drivers comprises an n channel mos transistor having a gate electrode supplied with an output of said row decoder, wherein said switching transistor comprises a second p channel mos transistor having a gate electrode supplied with a control signal generated by said control signal generation means, wherein said potential maintaining means comprises a resistor connected parallel to said second p channel mos transistor, a p channel mos transistor controlled according to a detected output of said detection circuit, connected in series with said resistor, and connected between said global boosted line and said segment boosted line via said resistor, a power supply potential node to which a power supply potential is supplied, a diode element connected between said power supply potential node and said segment boosted line, and a fuse connected in series with said diode element.
17. The semiconductor memory device according to claim 15 16, wherein said word line activation means comprises a second first second conductivity type transistor having a control electrode supplied with an inversion signal of said boosted decode signal, connected parallel to said first second conductivity type transistor.
19. The semiconductor memory device according to
21. The semiconductor memory device according to
a plurality of switching means, each connected between each of said plurality of segment boosted lines and said global boosted line, for selecting an electrical connection of each said segment boosted line with said global boosted line.
22. The semiconductor memory device according to
23. The semiconductor memory device according to
a spare memory array having a plurality of spare memory cells connected to a plurality of spare word lines, wherein said spare memory array comprises a spare memory cell group, said spare memory cell group including a predetermined number of said plurality of spare word lines, a spare segment boosted line provided corresponding to said spare memory cell group, supplied with a boosted potential which was to be applied to each segment boosted line corresponding to each memory cell group substituted with said spare memory cell group, spare word line select means for selecting any of said plurality of spare word lines, spare word line activation means responsive to an output of said spare word line select means for providing the potential of said spare segment boosted line to any of said predetermined number of spare word lines included in said spare memory cell group for activating the same, and inhibiting means for inhibiting the provision of said boosted potential to each segment boosted line corresponding to said each memory cell group substituted with said spare memory cell group.
24. The semiconductor memory device according to
a global boosted line to which a boosted potential higher than said power supply potential is supplied, a plurality of first switching means connected between each of said plurality of segment boosted lines and said global boosted line for selecting an electrical connection of each of said plurality of segment boosted lines with said global boosted line, and second switching means connected between said spare segment boosted line and said global boosted line for selecting an electrical connection of said spare segment boosted line with said global boosted line, wherein said inhibiting means comprises a plurality of fuse means each provided corresponding to said plurality of first switching means for rendering non-conductive each segment boosted line corresponding to each memory cell group substituted with said spare memory cell group and said global boosted line.
25. The semiconductor memory device according to
26. The semiconductor memory device according to
27. The semiconductor memory device according to
wherein said inhibiting means comprises a plurality of fuse means, each provided corresponding to each of said plurality of segment boosted lines for inhibiting provision of a boosted decode signal to each of said plurality of segment boosted lines corresponding to each of said plurality of memory cell groups substituted with said spare memory cell group.
28. The semiconductor memory device according to
29. The semiconductor memory device according to
33. The semiconductor memory device according to
said potential maintaining means comprises a fuse having one end connected to said resistor means and said switching means, and the other end connected to said segment boosted line.
36. The semiconductor memory device according to
said potential maintaining means comprises a resistor and a fuse connected in series.
37. The semiconductor memory device according to
39. A semiconductor memory device according to
40. A semiconductor memory device according to
a plurality of high resistance elements each provided corresponding to each segment boosted line, respectively, and connected between the corresponding segment boosted line and a node supplied potential.
41. A semiconductor memory device according to
42. The semiconductor memory device according to
said second n channel mos transistor is turned on when the corresponding one of said plurality of segment boosted lines is supplied with the low potential.43. A semiconductor memory device comprising a word line activation means for activating a word line, wherein said word line activation means comprises a first conductivity type transistor having a control electrode applied with a row decode signal, and a first electrode supplied with a boosted decode signal, and a second conductivity type transistor having a control electrode supplied with a row decode signal corresponding to said row decode signal, and connected in series with said first conductivity type transistor.44. The semiconductor memory device according to claim 43, wherein said word line activation means comprises a second, second conductivity type transistor having a control electrode supplied with an inversion signal of said boosted decode signal, connected parallel to said second conductivity type transistor.45. A semiconductor memory device comprising a word driver for activating a word line, wherein said word driver comprises a first p channel mos transistor having a gate electrode supplied with a row decode signal and a source electrode supplied with a boosted decode signal, and an n channel mos transistor having a gate electrode supplied with a row decode signal corresponding to said row decode signal, and connected in series with said first p channel mos transistor.46. The semiconductor memory device according to claim 45, wherein said word driver comprises a second n channel mos transistor having a gate electrode supplied with an inversion signal of said boosted decode signal, and connected parallel to said n channel mos transistor.
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1. Field of the Invention
The present invention relates to semiconductor memory devices, and more particularly, to a semiconductor memory device having a circuit structure for maintaining the level of a boosted signal line and a word driver connected to the boosted signal line, and a redundancy structure.
2. Description of the Background Art
FIG. 21 is a block diagram of a conventional semiconductor memory device.
Referring to FIG. 21, a semiconductor memory device of a dynamic RAM includes a memory array 161, a row address buffer 164, a row decoder 163, word drivers 162a-162h, a column address buffer 167, a column decoder 166, a sense amplifier 165, an input/output circuit 168, and a control circuit 169. Memory array 161 has bit lines and word lines disposed vertically and horizontally therein. Row address buffer 164 receives an externally applied row address. Row decoder 163 receives an output of row address buffer 164. Word drivers 162a-162h respond to an output of row decoder 163 to drive a word line. Column address buffer 167 receives an externally applied column address. Column decoder 166 receives an output of column address buffer 167. Sense amplifier 165 responds to an input from column decoder 166 to amplify a small current of memory array 161. Input/output circuit 168 carries out input/output of data with sense amplifier 165 via an I/O line. Control circuit 169 receives a row address strobe signal (/RAS), a column address strobe signal (/CAS), and a read/write control signal (W) to control the above device.
The operation of this semiconductor memory device will be described hereinafter. In response to an output of row address buffer 164 to which a row address is input, row decoder 163 selects a word line corresponding to a specified row address. For example, in FIG. 21, when the top most word line is selected, word driver 162a pulls up that word line. Then, sense amplifier 165 operates, whereby a small current read out from a memory cell at the crossing of a bit line and a word line in memory array 161 is amplified. In response to an output of column address buffer 167 to which a column address is input, column decoder 166 selects a bit line pair. The selected bit line pair is connected to an I/O line connected between input/output circuit 168 and sense amplifier 165. The data on the I/O line is amplified by a preamplifier in input/output circuit 168 to be transmitted to an output buffer for a read out operation. Externally applied data is transferred to the I/O line by a write buffer of input/output circuit 168 for a write operation.
There are some semiconductor memory devices that have a spare memory cell arranged besides memory array 161 of N (=nxm) bits for exchange of a defective bit.
In general, a memory cell includes a capacitor and an n channel MOS transistor. One electrode of the capacitor is fixed to a potential 1/2 Vcc which is half the power supply potential Vcc. The n channel MOS transistor has the gate electrode connected to a word line. The n channel MOS transistor is connected to the other electrode of the capacitor and a bit line. A predetermined potential is maintained at the other electrode of the capacitor to store data. When power supply potential VCC is to be transferred from a bit line to the other electrode of the capacitor without a voltage drop of the threshold voltage Vth of the n channel MOS transistor, a potential of a VPP level that is higher than VCC +Vth must be supplied from the word line to the gate electrode of this n channel MOS transistor. A semiconductor memory device that needs a potential of such a VPP level will be described hereinafter.
FIG. 22 is a block diagram of the main components of the semiconductor memory device of FIG. 21. FIG. 23 is a circuit diagram of the word driver of FIG. 22.
Referring to FIGS. 22 and 23, submemory arrays 171a and 171b are separated by a sense amplifier 172. At one side of submemory arrays 171a and 171b, row decoders 173a and 173b are provided, respectively. 4 n word lines are provided between row decoder 173a and submemory array 171a, and also between row decoder 173b and submemory array 171b. A word driver is provided at each word line. For example, word drivers 174a, 174b, 174c and 174d are provided at the upper 4 word lines disposed between row decoder 173a and submemory array 171a. Word drivers 175a, 175b, 175c and 175d are provided at the upper 4 word lines disposed between row decoder 173b and submemory array 171b. Boosted signal lines are disposed in the vertical direction with respect to the word lines disposed in the horizontal direction in the drawing.
The boosted signal line to which a boosted decode signal RX1 is input is connected to word drivers 174a and 175a. The boosted signal line to which a boosted decode signal RX2 is input is connected to word drivers 174b and 175b. The boosted signal line to which a boosted decode signal RX3 is input is connected to word drivers 174c and 175c. The boosted signal line to which a boosted decode signal RX4 is input is connected to word drivers 174d and 175d.
In other words, word lines are disposed so that word drivers 174a and 175a provided at the topmost word lines in submemory arrays 171a and 171b, respectively, receive boosted decode signal RX1 ; word drivers 174b and 175b provided at the respective second word lines receive boosted decode signal RX2 ; word drivers 174c and 175c provided at the respective third word lines receive boosted decode signal RX3 ; and word drivers 174d and 175d provided at the respective fourth word lines receive boosted decode signal RX4. Also, the word driver provided at the fifth word line receives boosted decode signal RX1, and the word driver provided at the sixth word line receives boosted decode signal RX2. Such boosted decode signals are repeatedly input to the word drivers.
In addition to a boosted decode signal, each word driver receives an output (signals WD, ZWD) of the row decoder.
As shown in FIG. 23, word driver 174 includes an n channel MOS transistor (N1) 181a, an n channel MOS transistor (N2) 181b, and an n channel MOS transistor (N3) 181c. n channel MOS transistor 181a functions as a transfer gate. A signal WD which is decoded to a level in row decoder 173a is applied to one of the source/drain thereof. Power supply voltage Vcc is applied to the gate thereof. n channel MOS transistor 181b receives boosted decode signal RX1 at its drain and an output of n channel MOS transistor 181a at its gate. n channel MOS transistor 181c has its gate supplied with an inversion signal ZWD of signal WD which is decoded to a level by row decoder 173b, and its source supplied with ground potential GND. The drain of n channel MOS transistor 181c is connected to the source of n channel MOS transistor 181b.
The operation thereof will be described hereinafter. Signal WD which is decoded to a certain level in row decoder 173a and an inversion signal thereof ZWD are input to the word driver provided at each word line. When each word driver attains a standby state (de-select state), signal WD attains a L level and inversion signal ZWD attains a H level. Therefore, n channel MOS transistor 181b is turned off, and n channel MOS transistor 181c is turned on. Therefore, word line WL is pulled to ground potential GND by n channel MOS transistor 181c, and is not activated.
When signal WD attains a H level, a node A is charged to the level of VCC -Vth which is power supply voltage VCC minus the threshold voltage via n channel MOS transistor 181a. Because inversion signal ZWD attains a L level when signal WD attains a H level, n channel MOS transistor 181a is off, and word line WL is not connected to ground potential GND. When node A is charged and the boosted level of the decoded boosted decode signal RX1 is applied to the drain of n channel MOS transistor 181b, node A is boosted by the coupling of the gate and drain, i.e. self boosted, so that n channel MOS transistor 181b is deeply turned on. As a result, word line WL is sufficiently charged to the boosted level to be selected. Therefore, access to a memory array is allowed.
A word line is selected to be pulled up only when signal WD and boosted decode signal RXl both attain a H level. The word line will not be selected in other combinations since it is not pulled up. In other words, decoding is also carried out in a word driver.
FIG. 24 shows the addition of a spare submemory array including a spare memory cell to be exchanged for a defective memory cell in the memory array of FIG. 22. In FIG. 24, elements corresponding to those of FIG. 22 have the same reference characters denoted, and their description will not be repeated.
Referring to FIG. 24, a spare memory cell array 191a is provided between memory cell array 171a and sense amplifier 172. A spare submemory array 191b is provided between submemory array 171b and a sense amplifier not shown. At one side of spare submemory arrays 191a and 191b, corresponding spare row decoders 192a and 192b are provided. A spare word line is disposed between spare row decoder 192a and spare submemory array 191a, and between spare row decoder 192b and spare submemory array 191b.
Spare word drivers 193a, 193b, 193c, and 193d are provided at respective spare word lines in order from the topmost spare word line disposed between spare row decoder 192a and spare submemory array 191a. Spare word drivers 194a, 194b, 194c and 194d are provided at respective spare word lines provided between spare row decoder 192b and spare submemory array 191b. Spare word drivers 193a and 194a provided at the respective topmost spare word lines receive boosted decode signal RX1. Spare word drivers 193b and 194b provided at the second spare word lines receive boosted decode signal RX2. Spare word drivers 193c and 194c provided at the third spare word lines receive boosted decode signal RX3. Spare word drivers 193d and 194d provided at the fourth spare word lines receive boosted decode signal RX4.
When a fault is generated in a memory cell in, for example, submemory array 171a, a fuse 195a provided in spare row decoder 192a is blown out. In response, the row address corresponding to the defective memory cell is substituted for the row address corresponding to a spare memory cell in spare memory array 191a to carry out exchange. Each of the structure of spare word drivers 193a-193d, 194a-194d is similar that of the word driver shown in FIG. 23, and their description will not be repeated.
There are semiconductor memory devices that use boosted voltage instead of a decode boosted signal. FIG. 25 is a block diagram of such a semiconductor memory device. FIG. 26 is a circuit diagram of a word driver shown in FIG. 25.
Referring FIGS. 25 and 26, submemory arrays 201a and 201b are divided by a sense amplifier 202. At one side of submemory arrays 201a and 201b, corresponding row decoders 203a and 203b are provided. A plurality of word lines are disposed between row decoder 203a and submemory array 201a with word drivers 205a-205h respectively. Similarly, a plurality of word lines are disposed between row decoder 203b and submemory array 201b with word drivers 206a-206h respectively.
Word drivers 205a-205h are connected to the same segment boosted signal line 207a. One end of segment boosted signal 207a is connected to one of the source/drain of switching transistor 204a. The gate of switching transistor 204a receives a control signal φ1. The other source/drain of switching transistor 204a is connected to a global boosted signal line 208a having a potential level of boosted voltage VPP. In response to control signal φ1, switching transistor 204a is turned on/off, whereby boosted voltage VPP is supplied to each of word drivers 205a-205h via segment boosted signal line 207a.
Similarly, word drivers 206a-206h are connected to a same segment boosted signal line 207b. The other end of segment boosted signal line 207b is connected to one source/drain of switching transistor 204b. The gate of switching transistor 204b receives a control signal φ2. The other source/drain of switching transistor 204b is connected to a global boosted signal line 208b having a boosted voltage VPP. Global boosted signal lines 208a and 208b are eventually connected to a VPP generation circuit not shown for generating boosted voltage VPP.
Word drivers 205a-205h and 206a-206h receive, not only boosted voltage VPP transmitted via switching transistor 204a and 204b, but also an inversion signal ZWD which is a signal completely decoded by row decoders 203a and 203b and converted into a boosted level. For example, word driver 205 includes a p channel MOS transistor (P1) 211, and an n channel MOS transistor (N1) 212, as shown in FIG. 26. p channel MOS transistor 211 has its gate supplied with decode signal ZWD, and its source connected to segment boosted signal line 207a. n channel MOS transistor 212 has its gate supplied with decode signal ZWD, and its source connected to ground potential GND. Thus, word driver 205a is formed as a CMOS inverter circuit that operates between a supplied boosted potential VPP and ground potential GND.
An operation of particularly submemory array 201a will be described hereinafter.
When control signal φ1 attains a level of boosted voltage VPP, switching transistor 204a is off. Therefore, boosted voltage VPP is not supplied to each of word drivers 205a-205h. When control signal φ1 attains the level of ground potential GND, switching transistor 204a is on. Boosted voltage VPP is supplied to each of word drivers 205a-205h via segment boosted signal line 207a when switching transistor 204a is on.
When signal ZWD output from row decoder 203a attains the level of boosted voltage VPP, p channel MOS transistor 211 is off and n channel MOS transistor 212 is on. Therefore, word line WL is pulled down to ground potential GND by n channel MOS transistor 212 to attain a standby (de-select) state. When signal ZWD attains a L level, n channel MOS transistor 212 is off and is not in conduction with ground potential GND. Therefore, p channel MOS transistor 211 attaining an on state causes word line WL to be charged sufficiently to the level of boosted potential VPP. Thus, a sufficiently charged word line WL is selected.
There are also semiconductor memory devices that have switching transistors removed, as shown in FIG. 27. Boosted voltage VPP is directly applied to a word driver via a global boosted signal line 221.
In recent years, the circuit complexity has increased as the memory capacity becomes greater, resulting in increase of the consumed current. It is envisioned that consumed current can be suppressed if the circuit complexity is simplified. However, such simplification in circuitry should not cause reduction in reliability thereof. It is also important to speed access in a semiconductor memory device. Furthermore, the exchange efficiency of a spare memory in the case of a fault in a submemory array and the chip area of the spare submemory array are also important factors. A semiconductor memory device with a high exchange efficiency and a small chip area is desired.
Here, exchange efficiency refers to the unit of a group of memory cells that are exchanged in using one spare submemory array when a defective submemory cell is exchanged for a proper spare memory cell. This means that a large group requires a larger memory capacity on the basis of a spare submemory array with respect to one exchange. This will cause increase in the chip area of the spare submemory array.
In recent years, a semiconductor memory device that carries out exchange, not in the unit of word lines as shown in FIG. 24, but in the unit of submemory arrays, has attracted a lot of attention. Such a semiconductor memory device is disclosed in the Journal of Technical Papers of ISSCC 93, pp. 48-49.
However, conventional semiconductor memory devices have problems set forth in the following.
In the semiconductor memory device shown in FIG. 25, when submemory array 201a is de-selected, and switching transistor 204a attains a non-conductive state, charge will leak from segment boosted signal line 207a via each of word drivers 205a-205h due to subthreshold leakage current therein. This causes reduction in potential of segment boosted signal line 207a from the level of boosted potential VPP. When submemory array 201a is selected and transistor 204a is conductive, segment boosted signal line 207a must be boosted up to the level of boosted potential VPP again. If the potential of segment booted signal line 207a was lowered to a level in the vicinity of ground potential, the boosting up to the level of boosted potential VPP will be time consuming, resulting in a slow access time.
Furthermore, in a semiconductor memory that carries out exchange in the unit of submemory arrays, a submemory array is directly exchanged with a spare submemory array. Therefore, the exchange efficiency is low. Furthermore, it is difficult to increase the number of spare submemory arrays from the standpoint of the chip area. Therefore, it was difficult to improve the yield.
There are also problems in a semiconductor memory device that carries out exchange in a word line unit as shown in FIG. 24. When leakage occurs in a segment boosted signal line due to a defective word line, all the word lines associated with that segment boosted signal line will also become defective. Therefore, the exchange efficiency will become the same as that of exchange carried out in the unit of submemory arrays.
In the semiconductor memory device of FIG. 25, the transition rate of a word driver from a standby state to an active state depends upon the potential of a segment boosted signal line. More specifically, when a switching transistor is off, the potential will become as low as the level of ground potential in the worst case due to junction leakage and subthreshold leakage. During the time period of the potential of the segment boosted signal pulled up to the level of boosted potential VPP, the word driver cannot attain an active state. Therefore a high speed operation could not be carried out.
In the semiconductor memory device shown in FIG. 27 where switching transistors are removed and boosted voltage VPP is supplied directly from global boosted signal line 221 to a word driver, there is a problem that the consumed current becomes so great that it causes standby current fault when current begins to leak from global boosted signal line 221 due to a fault in a word driver. When the word driver shown in FIG. 26, for example, is applied to the semiconductor memory device shown in FIG. 27, such a fault with respect to a word driver includes the generation of a great leakage current due to a great potential difference between a boosted voltage VPP and ground voltage GND applied on p channel MOS transistor 211. Furthermore, the output of the row decoder applied to the word driver must be completely decoded, causing increase in the circuit complexity of the row decoder. This results in a problem that the layout pitch is reduced with respect to a row decoder.
In the word driver of FIG. 23, if the self boost by means of coupling at n channel MOS transistor 181b is not sufficient, the selected word line will not have a sufficient level to be driven. This results in an insufficient opening of the transfer gate to cause erroneous operation. Adjustment was made to carry out a complete self boost by delaying boosted decode signal RX1 by delay means. However, the delay time by the delay means varies due to a change in the process, resulting in the possibility of an erroneous operation. Increase in the delay time of boosted decode signal RX slows the access time. It is extremely difficult to design the timing in which a complete self boost is carried out without delay.
When boosted decode signal RX1 is applied to n channel MOS transistor 181b with node A at the level of VCC -Vth, the potential of word line WL will rise only to the level of VCC -Vth. It is therefore necessary to input boosted decode signal RX1 after node A is sufficiently charged. More specifically, it is necessary to carry out the so-called double boosting for node A to be boosted to the level of VCC +VPP -Vth to transmit boosted voltage VPP of the boosted decode signal to word line WL. However, a great potential difference is applied between the source and gate of n channel MOS transistor 181b, resulting in the possibility of the reliability of n channel MOS transistor 181b being degraded.
In view of the foregoing, an object of the present invention is to provide a semiconductor memory device that has consumed power due to leakage at a boosted signal line suppressed.
Another object of the present invention is to improve the exchange efficiency of a semiconductor memory device that has exchange carried out.
A further object of the present invention is to provide a semiconductor memory device that has the chip area of the entire memory array reduced.
A still further object of the present invention is to provide a semiconductor memory device that provides a voltage of a potential level between a boosted potential and a ground potential to a word driver so that the word driver is rendered active speedily.
Yet another object of the present invention is to provide a semiconductor memory device including a word driver that can have the chip area and nuclear of elements of a decoder reduced.
According to an aspect of the present invention, a semiconductor memory device includes a memory array (MA0) having a plurality of memory cells (MC) connected to a plurality of word lines (WL0 -WL255), a global boosted line (GL) to which a boosted potential (Vpp) higher than power supply potential Vcc is applied, a segment boosted line (SL0) provided corresponding to the submemory array (MA0), a word line select unit (RD0) for selecting any of the plurality of word lines (WL0 -WL255), a word line activation unit (DRVG0) responsive to an output from the word line select unit (RD0) for providing the potential of the segment boosted line (SL0) to a selected one of the plurality of word lines (WL0 -WL255) to activate the same, a first switching unit (6) connected between the segment boosted line (SL0) and the global boosted line (GL) for selecting an electrical connection of the segment boosted line (SL0) with the global boosted line (GL), and a potential maintaining unit (7, 8, 17, 18, 19, 220, Vcc) for maintaining the potential of the segment boosted line (SL0) at a potential between the ground potential and the boosted potential (Vpp) applied to the global boosted line (GL).
According to the present aspect, the potential maintaining unit maintains the potential of the segment boosted line at a potential between the ground potential and the boosted potential, so that the consumed current required to generate a boosted voltage is only that of the difference between the boosted potential and the potential. Therefore, consumed current can be suppressed.
According to the present aspect, the potential between the boosted potential and the ground potential is supplied to a word driver in a word line activation unit by the potential maintaining unit, so that the word driver can pull up the word line speedily. Thus, a high speed access can be achieved.
According to another aspect of the present invention, a semiconductor memory device includes a word line activation unit (DRV0) for activating a word line (WL0). The word line activation unit (DRV0) includes a first first conductivity type transistor (261) having a control electrode supplied with a row decode signal (ZWD) and a first electrode supplied with a boosted decode signal (RXik), and a second conductivity type transistor (271) connected in series with the first first conductivity type transistor (261), having a control electrode supplied with the same row decode signal (ZWD).
According to the present aspect, a boosted decode signal is applied to the word line activating unit (DRV1). Because a boosted voltage is not always supplied, consumed current can be suppressed.
According to the present aspect, in addition to the above advantage, a difficult timing design is not required. Therefore, a word line activation unit (DRV0) that accesses a memory at high speed is provided. Thus, the layout pitch of a row decoder and the like that provides a boosted decode signal to the word line activation unit (DRV0) can be improved.
According to a further aspect of the present invention, a semiconductor memory device includes a memory array (MA0) having a plurality of memory cells (MC) connected to a plurality of word lines (WL0 -WL255). The submemory array (MA0) includes a plurality of memory cell groups (SBMA00 -SBMA03). Each memory cell group array includes a predetermined number of the plurality of word lines (WL0 -WL255). The semiconductor memory device further includes a plurality of segment boosted lines (SL00 -SL03), each provided corresponding to each memory cell group (SBMA00 -SBMA03), and to which a boosted potential (Vpp) higher than the power supply potential (Vcc) is selectively applied, a word line select unit (RD0) for selecting any of the plurality of word lines (WL0 -WL255), and a word line activation unit (DRVG0) responsive to an output from the word line select unit (RD0) for transmitting the potential of a segment boosted line to which the boosted potential (Vpp) is selectively applied out of the plurality of segment boosted lines (SL00 -SL03) to any of the predetermined number of word lines in each memory cell group.
According to the present aspect, the submemory array is divided into a plurality of memory cell groups with corresponding segment boosted signal lines. A boosted potential is supplied to only the segment boosted signal line that has leakage. Therefore, the consumed current is suppressed.
The semiconductor memory device of the present aspect further includes a spare memory array (SMA) having a plurality of spare memory cells connected to a plurality of spare word lines. The spare memory array (SMA) includes a spare memory cell group (SSBMA0), wherein the spare memory cell group (SSBMA0) has a predetermined number of the plurality of spare word lines. The semiconductor memory device further includes a spare segment boosted line (SSLso) provided corresponding to the spare memory cell group (SSBMA0), supplied with a boosted potential (Vpp) which was to be applied to each segment boosted line (SL00 -SL03) corresponding to each memory cell group (SBMA00 -SBMA03) substituted with the spare memory cell group (SSBMA0), a spare word line select unit (SRD) for selecting any of the plurality of spare word lines, a spare word line activation unit (SDRVG) responsive to an output of the spare word line select unit (SRD) for providing the potential of the spare segment boosted line (SSLso) to any of the predetermined number of spare word lines included in the spare memory array (SSBMA0) for activating the same, and an inhibiting unit (49, 57, 58, 59, 60, 301, 305, 307, 309, 311) for inhibiting the provision of the boosted potential (Vpp) to each segment boosted line (SL00 -SL03) corresponding to each memory cell array (SBMA00 -SBMA03) substituted with the spare memory cell array (SSBMA0).
According to the present aspect, in addition to the above advantage, exchange is carried at the unit of memory cell groups which are formed corresponding to a segment boosted signal line. Therefore, the exchange efficiency can be improved, and the chip area of the spare memory cell group can be reduced.
The foregoing and other objects, features, aspects and advantages of the present invention will become more apparent from the following detailed description of the present invention when taken in conjunction with the accompanying drawings.
FIG. 1 is a block diagram showing a semiconductor memory device according to a first embodiment of the present invention.
FIG. 2 shows a circuit for generating a control signal φ0 which is an example of a control signal φi input to the switching transistor of FIG. 1.
FIGS. 3-5 are diagrams showing the main components of a semiconductor memory device according to second to fourth embodiments, respectively, of the present invention.
FIGS. 6A-6C are diagrams for describing the operation of the circuit of FIG. 5.
FIG. 7 is a block diagram of a semiconductor memory device according to a fifth embodiment of the present invention.
FIG. 8 shows a circuit for generating a control signal φ0 which is an example of a control signal φi which is input to the switching transistor of FIG. 7.
FIG. 9 is a block diagram schematically showing a semiconductor memory device according to a sixth embodiment of the present invention.
FIG. 10 is a circuit showing a word driver of a semiconductor memory device according to a seventh embodiment of the present invention;
FIG. 11 shows a circuit for generating a boosted decode signal RXik applied to the word driver of FIG. 10.
FIGS. 12A and 12B are diagrams for describing the effect of the seventh embodiment of FIG. 10.
FIG. 13 is a circuit diagram showing a word driver of a semiconductor memory device according to an eighth embodiment of the present invention.
FIG. 14 is a block diagram of a semiconductor memory device according to a ninth embodiment of the present invention.
FIG. 15 shows a circuit for generating a control signal φik which is applied to the switching transistor of FIG. 14.
FIG. 16 is a block diagram of a semiconductor memory device according to a tenth embodiment of the present invention.
FIG. 17 shows a circuit for generating a control signal φik applied to the switching transistor of FIG. 16.
FIG. 18 is a block diagram schematically showing a semiconductor memory device according to a twelfth embodiment of the present invention.
FIG. 19 shows a circuit for generating the boosted decode signal RXik of FIG. 18.
FIG. 20 is a block diagram schematically showing a semiconductor memory device according to a thirteenth embodiment of the present invention.
FIG. 21 is a block diagram schematically showing a conventional semiconductor memory device.
FIG. 22 is a block diagram of FIG. 21 showing the main components enlarged.
FIG. 23 is a circuit diagram of the word driver of FIG. 22.
FIG. 24 shows an additional provision of a spare submemory array for exchanging a defective memory cell in the submemory array of FIG. 22.
FIG. 25 is a block diagram of another conventional semiconductor memory device.
FIG. 26 is a circuit diagram of a word driver of FIG. 25.
FIG. 27 is a block diagram of a further conventional semiconductor memory device.
Referring to FIG. 1, a semiconductor memory device 1 includes a plurality of submemory arrays MA0 -MA31, a global boosted signal line GL to which a boosted voltage VPP is applied, segment boosted line signals SL0 -SL31, a word line select unit for selecting word lines WL0 -WL255 arranged in submemory array MA0 -MA31, sense amplifier bands SA0 -SA32, and switching units SW0 -SW31 for selectively switching the connection of global boosted signal line GL to segment boosted signal lines SL0 -SL31. Semiconductor memory device 1 further includes a spare memory array SMA that can be substituted with any of submemory arrays MA0 -MA31, a spare segment boosted signal line SSL, a spare word line select unit for selecting a spare word line connected to spare memory array SMA, a spare sense amplifier band SSA, and a spare switching unit SSW for selectively switching the connection of global boosted signal line GL to spare segment boosted signal line SSL.
Plurality of submemory arrays MA0 -MA31 and spare memory array SMA include a plurality of memory cells MC connected between 256 word lines and bit lines pairs BL0, /BL0 -BLn, BLn. Each memory cell MC includes a capacitor 3 and an n channel MOS transistor 2 connected between capacitor 3 and bit lines BL0 -BLn (/BL0 -/BLn). The gate electrode of each n channel MOS transistor 2 is connected to respective word lines WL0 -WL255.
The word line select unit includes word driver groups DRVG0 -DRVG31, and row decoders RD0 -RD31. Word driver groups DRVG0 -DRVG31 are respectively formed of word drivers DRV0 -DRV255 provided at word lines WL0 -WL255, respectively. Each of word drivers DRV0 -DRV255 includes n channel MOS transistor 4 and p channel MOS transistor 5 to which the output signals of row decoders RD0 -RD31 are applied. p channel MOS transistor has its well potential connected to boosted potential VPP. Bit line pairs BL0, /BL0 -BLn, /BLn are connected to sense amplifier bands SA0 -SA32. Sense amplifier bands SA0 -SA32 include a sense amplifier, an IO gate and a bit line precharge/equalizer circuit, and is connected to I/O line pairs IO0, /IO0-IO32, /IO32.
Similarly, the spare word line select unit includes a spare word driver group SDRG and a spare row decoder SRD. Bit line pairs BL0, /BL0 -BLn, /BLn are connected to a spare sense amplifier band SSA. The internal sense amplifier is connected to a spare I/O line pair SIO, /SIO.
Each of switching units SW0 -SW31 is connected between global boosted signal line GL and each of segment boosted signal line SL0 -SL31. Each of switching units SW0 -SW31 includes a switching transistor 6 to which control signals φ0 -φ31 are respectively input to the gate thereof, and a series element 223 of a high resistor 7 and a fuse 8 provided parallel to switching transistor 6. Similarly, spare switching unit SSW is connected between global boosted signal line GL and spare segment boosted signal line SSL. Spare switching unit SSW includes a switching transistor 9 to which control signal φs is applied to its gate thereof, and a series element 224 of a high resistor 10 and a fuse 11 provided parallel to switching transistor 9.
High resistor 7 in switching units SW0 -SW31 and high resistor 10 in spare switching unit SSW are resistors of a long channel length and a small channel width to obtain high resistance with a small layout area. High resistor 7 or high resistor 10 is used as the channel resistor of a p channel MOS transistor, connected between global boosted signal line GL and segment boosted signal line SL0 -SL31 or spare segment boosted signal line SSL, to which ground potential is applied to its gate electrode. The resistance of the channel resistor is set to a high value in comparison with the ON resistance of switching transistors 6 and 9.
A circuit for generating a control signal φi that is input to the gate of a switching transistor will be described hereinafter. As shown in FIG. 2, a circuit generating a control signal φ0 includes a level conversion unit 101, a NAND gate 111, a fuse 12, and a resistor 13. Fuse 12 is connected between power supply voltage VCC and a node C. Resistor 13 is connected between node C and ground potential GND. An output according to the state of fuse 12 and resistor 13 from node C is applied to one input of NAND gate 111. A memory array select signal X0 is applied to the other input of NAND gate 111. The output of NAND gate 111 is applied to level conversion unit 101.
Level conversion unit 101 includes an n channel MOS transistor 15a having a gate to which the output of NAND gate 111 is input and a source connected to ground potential GND, an inverter 14 to which the output of NAND gate 111 is input, and an n channel MOS transistor 15b having a gate supplied with the output of inverter 14 and a source connected to ground potential GND. Level conversion unit 101 further includes a p channel MOS transistor 16b having a gate connected to the drain of n channel MOS transistor 15a via a node A, and a source connected to boosted voltage VPP, and a p channel MOS transistor 16a having a gate connected to the drain of n channel MOS transistor 15b via node B and a source connected to boosted voltage VPP.
The drain of p channel MOS transistor 16a is connected to the drain of n channel MOS transistor 15a and the gate of p channel MOS transistor 16b via node A. The drain of p channel MOS transistor 16b is connected to the drain of n channel MOS transistor 15b and the gate of p channel MOS transistor 16a via node B. Control signal φ0 is applied from node B of level conversion unit 101 to the gate of switching transistor 6.
The operation of the circuit for generating a control signal φ0 shown in FIG. 2 will be described hereinafter.
When there is no leakage in segment boosted signal line SL0, fuse 12 is not blown out. The output of NAND gate 111 attains a L level when memory array select signal X0 attains a H level, and control signal φ0 which is the output of level conversion unit 101 attains a L level to turn on switching transistor 6. As a result, submemory array MA0 is selected. When memory array select signal x0 attains a L level, control signal φ0 attains a H level to turn off switching transistor 6. Therefore, submemory array MA0 is not selected.
When there is a great leakage in a segment boosted signal line SL0, fuse 12 is blown out to prevent boosted potential VPP of global boosted signal line GL from being supplied to segment boosted signal line SL0 when switching transistor 6 is turned on. Therefore, the output of NAND gate 111 always attains a H level, and control signal φ0 which is the output of level conversion unit 101 always attains the level of boosted potential VPP. Therefore, switching transistor 6 always attains an off state. As a result, global boosted signal line GL is not connected to segment boosted signal line SL0, so that the VPP generation circuit that generates boosted potential VPP does not operate. Thus, consumed current is suppressed.
When fuse 8 is blown out or when switching transistor 6 is off, the well potential of p channel transistor 5 attains a floating state if the well potential and the source potential are equal. Therefore, the well potential of p channel transistor 5 is connected to boosted potential VPP because there is a problem that latch up or the like easily occurs.
It is to be noted that connection leakage current or subthreshold leakage current is generated in switching transistors 4 and 5 forming word drivers DRV0 -DRV255. Therefore, charge leaks from segment boosted signal line SLi or from spare segment boosted signal line SSL even when submemory array MAi or spare memory array SMA corresponding to switching transistors 4 and 5 is not selected and switching transistors 6 and 9 to which control signal φi of the level of boosted potential VPP was provided attains a non-conductive state. The potential of segment boosted signal line SLi or spare segment boosted signal line SLL will become lower than the level of boosted potential VPP due to the charge leakage.
In the first embodiment, high resistors 7 and 10 are provided between global boosted signal line GL and segment boosted signal line SLi or spare segment boosted signal line SSL, so that a small current flows corresponding to the leaking charge via high resistors 7 and 10. Therefore, segment boosted signal line SLi or spare segment boosted signal line SSL is maintained at the level of boosted potential VPP. When submemory array MAi is selected to cause control signal φi to attain ground potential and switching transistor 6 conducts, boosted voltage VPP is immediately transmitted from segment boosted signal line SLi to the word line by the word driver receiving a decode signal of a L level. Thus, a high speed read out can be carried out.
There is a case where a fault is generated in any of word drivers DRV0 -DRV255 due to attachment of a contaminant or the like, causing a great leakage current flow from segment boosted signal line SLi via the defective word driver. Here, switching transistor 6 attains a non-conductive state, and the low current from high resistor 7 cannot compensate for this great leakage current. There is the possibility that the potential of the segment boosted signal line becomes as low as a level near ground potential. Here, fuse 8 of segment boosted signal line SLi belonging to the word driver in which a fault is generated is blown out, whereby the low current flowing from global boosted signal line GL to segment boosted signa line SLi is cut off. Therefore, consumed current is reduced.
Even though word drivers DRV0 -DRV255 with respect to submemory array MAi substituted with spare memory array SMA are not used, junction leakage current or subthreshold leakage current is generated in word drivers DRV0 -DRV255 belonging to the not-used submemory array MAi. By blowing out fuse 8 belong to that segment boosted signal line SLi the small current, although low in level, is prevented from being supplied to segment boosted signal line SLi by high resistor 7. Therefore, consumed current is reduced.
FIG. 3 shows the main components of a semiconductor memory device according to a second embodiment of the present invention, and corresponds to the portion of switching units SW0 -SW31 and spare switching unit SSW of FIG. 1. In the following, only the components differing from those of FIG. 1 will be described.
Referring to FIG. 3, a diode device 17 is provided instead of high resistor 7. Diode device (circuit) 17 includes an n channel MOS transistor of a threshold voltage Vth (for example 0.6 V) connected between the power supply node to which power supply potential VCC (for example 3.3 V) is applied and a segment boosted signal line SLi (i=0, 1, 2, . . . , 31), and having a gate electrode connected to the power supply node. When the potential of segment boosted signal line SL0, for example, becomes lower than VCC -Vth, diode device 17 conducts so that charge is supplied from the power supply potential node to segment boosted signal line SL0. Thus, the potential is maintained at VCC -Vth. When the potential of the segment boosted signal line becomes higher than VCC -Vth, diode device 17 is rendered non-conductive. A fuse 18 is provided between diode device 17 and segment boosted signal SL0 via a node D. A series element 225 is formed of diode device 17 and fuse 18.
Submemory array MAi and spare memory array SMA will be described hereinafter focusing on submemory array MA0. When there is a leakage due to a defect in submemory array MA0 and word drivers DRV0 -DRV255, or a leakage in segment boosted signal line SL0 by adherence of a contamination, or when there is a defect in submemory array MA0 without any leakage, global boosted signal line GL must be disconnected from segment boosted signal line SL0. However, this disconnection may be avoided depending upon the leakage state by applying power supply potential VCC provided from diode device 17.
For example, when switching transistor 6 attains a non-conductive state in the case where there is no defect except that the leakage current is greater than the design value due to a simple offset in the manufacturing process, charge is supplied by diode circuit 17 from the power supply potential node to segment boosted signal line SL0 to compensate for the leakage current. The potential of segment boosted signal line SL0 will not be extremely reduced, and is maintained at the level of VCC -Vth. It is not necessary to disconnect global boosted signal line GL from segment boosted signal line SL0 when charge is supplied from global boosted signal line GL to segment boosted signal line SL0 so that segment boosted signal line SL0 is promptly restored to the level of boosted potential VPP when switching transistor 6 conducts.
However, when the potential of segment boosted signal line SL0 is lowered to the level in the vicinity of ground potential even when charge is supplied by diode device 17 from the power supply potential node to segment boosted signal line SL0, it is necessary to disconnect global boosted signal line GL from segment boosted signal line SL0. In this case, fuse 12 of the circuit generating control signal φ0 shown in FIG. 2 is to be blown out. As a result, the signal applied to the gate of switching transistor 6 attains the level of VPP, whereby switching transistor 6 is turned off. By blowing out fuse 18 provided between diode device 17 and segment boosted signal line SL0, the VPP generation circuit that generates boosted potential VPP applied to global boosted signal line GL will not operate. Therefore, consumed current is suppressed.
Because diode circuit 17 is provided between the power supply node and the segment boosted signal line in the second embodiment, the current is maintained at VCC -Vth even when there is a slight leakage of current from the segment boosted signal line when the switching transistor attains a non-conductive state. Therefore, the potential of the segment boosted signal line is not lowered to the level in the vicinity of the ground potential. Boosted potential VPP can be promptly transmitted to the selected word line when switching transistor 6 conducts.
Similar to the first embodiment, fuse 18 is provided between diode circuit 17 and segment boosted signal line SL0. When there is a fault in a word driver caused by the adherence of a contaminant causing a great amount of leakage current from segment boosted signal line SL0 via this word driver and when switching transistor 6 attains a non-conductive state, fuse 18 is to be blown out. As a result, the current flowing from the power supply potential node to the segment boosted signal line via diode circuit 17 is cut off, so that consumed current is reduced.
Even when the word driver is proper and spare memory array SMA is exchanged due to a defective submemory array MA0, the blow out of fuse 18 prevents diode circuit 17 from compensating for the junction leakage current or subthreshold leakage current of the driver in submemory array MAo which is no longer used. Therefore, consumed current is reduced.
Because charge is supplied to segment boosted signal line SL0 from the power supply potential node, and not from global boosted signal line GL as in the first embodiment, a greater amount of current can be conducted in comparison with that of the first embodiment even if the consumed power for this provision is identical to that of a first embodiment. Therefore, in the case where the consumed current is limited and there is not defect except that the leakage current from the segment boosted signal is greater than the design value due to offset in the manufacturing process, a current for compensating for the leakage current is supplied from the power supply node to segment boosted signal line SL0 via diode circuit 17. Therefore, the potential of segment boosted signal line SL0 is maintained at the level of VCC -Vth, so that submemory array MA0 does not have to be exchanged by spare memory array SMA. Thus, the yield is improved.
Suppression of a leakage current is attributed to necessity of a great amount of power being consumed due to generation of boosted potential VPP from power supply potential VCC by a charge pumping operation. Assuming that the power directly consumed from power supply potential VCC is 1 mW, for example, the power consumed from boosted potential VPP become 3 mW which is three times that of the case of power supply potential VCC on the basis that 2 mW is required to generate 1 mW by boosted potential VPP. If power consumption is limited to 1 mW, a current of 1 mW can be conducted from power supply potential VCC. However, only current of 0.33 mW can be conducted from boosted potential VPP which is 1/3 the former.
FIG. 4 shows the main components of a semiconductor memory device according to a third embodiment of the present invention. The third embodiment is a combination of the first embodiment and the second embodiment.
Referring to FIG. 4, there are provided a series element 223 formed of high resistor 7 and fuse 8, and a series element 225 formed of a diode circuit 17 and a fuse 18. Diode circuit 17 is connected to power supply potential VCC. The output of diode circuit 17 is applied to word driver DRV0. Fuse 18 is provided between node F and diode circuit 17. The provision of fuse 18 is not limited to the position between node F and diode circuit 17, and may be provided between power supply potential VCC and diode circuit 17. Because the resistance of high resistor 7 is higher than the on resistance of diode circuit 17, diode circuit 17 can conduct a current greater than that of high resistor 7.
When there is a leakage in the node of segment boosted signal line SL0, boosted potential VPP is supplied to word driver DRV0 via high resistor 7. However, the potential level of segment boosted signal line SL0 will be reduced if there is only high resistor 7 when the leakage becomes greater. However, when the potential level of segment boosted signal line SL0 becomes as low as the level of VCC -Δ (junction potential), power supply potential VCC is supplied to word driver DRV0 via diode 17.
The current compensating for the leakage is not all generated by the VPP generation circuit, and the sum of the current supplied via high resistor 7 and that supplied via diode circuit 17 is the current that compensates for the leakage. The sum of the current consumed at the VPP generation circuit and the current that is directly consumed from power supply potential VCC becomes the consumed current for compensating for the leakage. Therefore, the consumed current from VPP generation circuit to high resistor 7 is suppressed.
If the level of the leakage is such that can be compensated for by blowing out fuse 8, this circuit is similar to that of the embodiment shown in FIG. 3. When both fuses 8 and 18 are to be blown out, global boosted signal line GL is completely disconnected from segment boosted signal line SL0 by blowing out also fuse 12 shown in FIG. 2 to set control signal φ0 at the level of VPP.
Similar to the first embodiment, by providing high resistor 7 parallel to switching transistor 6, high speed read out can be carried out in the third embodiment. Furthermore, because diode circuit 17 is provided between the power supply node and the segment boosted signal line as in the second embodiment, the case where only the leakage current from segment boosted signal line is greater than the design value due to offset in the manufacturing process and there is no other default can be repaired. Therefore, the yield is improved.
Fuses 8 and 18 are provided between high resistor 7 and segment boosted signal line SL0, and diode circuit 17 and segment boosted signal line SL0. When the leakage current from segment boosted signal line SL0 is great and switching transistor 6 attains a non-conductive state with the potential of segment boosted signal line SL0 not boosted to the level of boosted potential VPP but at the level in the vicinity of VCC -Vth, fuse 8 is to be blown out. As a result, the current flowing from global boosted signal line GL via high resistor 7 is cut off, so that consumed current is reduced.
Fuses 8 and 18 are to be blown out in the case where the leakage current is so great that the potential of segment boosted signal line SL0 is reduced to the level in the vicinity of ground potential despite the supply of charge to segment boosted signal line SL0 by high resistor 7 and diode circuit 17, and in the case where spare memory array SMA is substituted for submemory array MA0 which has a defect although word driver DRV0 is proper. Therefore, high resistance 7 and diode circuit 17 can be prevented from compensating for the leakage current in submemory array MAi which is no longer used. Therefore, consumed current is reduced.
FIG. 5 shows the main components of a semiconductor memory device according to a fourth embodiment of the present invention. FIG. 6 is a diagram for describing the embodiment of FIG. 5.
In the fourth embodiment, fuse 8 of FIG. 4 is removed, and a switching transistor 19 is provided in series with high resistor 7. A VPP generation circuit 20 which was not shown previously is connected to global boosted signal line GL to supply boosted potential VPP. A VPP level detector 21 is provided for detecting the potential level of boosted potential VPP supplied from VPP generation circuit 20 to output a signal VPe for the activation or deactivation of VPP generation circuit 20. The output of VPP level detector 21 is applied to a delay circuit 22. The output of delay circuit 22 is applied to the gate of switching 6.
When the potential level of global boosted signal line GL becomes lower than a predetermined set value, VPP level detector 21 activates VPP generation circuit 20 by its output signal VPe. There may be three potential levels as shown in FIGS. 6A-C depending on the level of the leakage, if any, in segment boosted signal line SL0. Here, the potential level of segment boosted signal line SL0 is referred to as VPP 1'.
When the leakage is small and the level of VPP 1' falls to the detect level for VPP detector 21 to operate as shown in FIG. 6(A), VPP generation circuit 20 receiving the output signal VPe is activated. This causes the level of boosted potential VPP and the level of VPP 1' to increase. Then, output signal VPe of VPP level detector 21 is applied to delay circuit 22. The delay signal is applied to the gate electrode of switching transistor 19 to turn off switching transistor 19.
Then, VPP generation circuit 20 is deactivated by VPP level detector 21. Also, a delay signal of the signal that deactivated VPP generation circuit 20 is applied to the gate electrode of switching transistor 19, whereby switching transistor 19 is turned on. When the level of VPP 1' begins to fall, VPP generation circuit 20 is activated again by output signal VPe by VPP level detector 21. By carrying out such repetition, the level of VPP 1' will fall only intermittently as shown in FIG. 6(A). This means that VPP generation circuit 20 is activated only intermittently, so that consumed current will not increase. Thus, the consumed current is maintained below the specification value of the standby current.
As shown in FIG. 6(B), when the leakage is greater than that shown in FIG. 6(A), the reduction in the level of VPP 1' to the detect level where VPP level detector 21 operates causes activation of the VPP generation circuit by output signal VPe. However, the leakage is greater than the current supplied by VPP generation circuit 20, so that the level of VPP 1' is further reduced. When the VPP 1' falls to the level of VPP -Δ, current from power supply potential VCC is supplied via diode device 17 to cease reduction in the level.
Because VPP generation circuit 20 continues activation as long as fuse 8 is not blown out n FIG. 4, the current which is the sum of the current generated at VPP generation circuit 20 and the current flowing from power supply potential VCC via diode circuit 17 becomes the standby current, resulting in a greater value. In FIG. 5, when the level of VPP 1' becomes lower than the detect level, output signal VPe, of VPP level detector 21 is applied to the gate electrode of switching transistor 19 via delay circuit 22. Switching transistor 19 is turned off, so that there is no leak path in global boosted signal line GL itself. Therefore, the potential level VPP of global boosted signal line GL is restored, and VPP generation circuit 20 is deactivated.
When the level of potential VPP 1' of segment boosted signal line SL0 falls to the level of VCC -Δ, the current by power supply potential VCC is supplied to the word driver DRV0 side via diode circuit 17. Therefore, the level of VPP 1' is maintained at VCC -Δ, and reduction in the level is suppressed. Therefore, the current for compensating for the leakage of VPP 1' is only that provided from power supply potential VCC via diode circuit 17. Therefore, the standby current is reduced, to suppress consumed current.
When the leakage is too great as shown in FIG. 6C, the level of potential VPP 1' of segment boosted signal line SL0 is also reduced by the current according to power supply potential VCC by diode circuit 17. In this case, control signal φ0 applied to switching transistor 6 is controlled by the circuit shown in FIG. 2 to set the boosted potential to a H level, and fuse 18 is blown out. When the circuit of FIG. 2 is not used and control signal φ0 attains a L level, a fuse may be provided between node G and word driver DRV0 which is to be blown out. It is not always necessary to provide a fuse 18.
FIG. 7 is a block diagram schematically showing a semiconductor memory device according to a fifth embodiment of the present invention. FIG. 8 shows a circuit for generating a control signal φI (i=0, 1, 2, . . . , 31).
Components of the fifth embodiment differing from those shown in FIG. 1 will be described hereinafter.
Referring to FIG. 7, the present embodiment is characterized in a switching unit SWi provided corresponding to submemory array MAi, and a spare switching unit SSW provided corresponding to spare submemory array SMA. More specifically, fuse 8 of switching unit SWi of FIG. 1 is removed, and a fuse 220 is connected to segment boosting signal line SLi in series with the parallel element of switching transistor 6 and high resistor 7. A series element 223 is formed by high resistor 7 and fuse 220. Fuse 11 of spare switching unit SSW is removed.
Attention is focused on a circuit generating a control signal φ0 as a circuit for generating a control signal φi. Referring to FIG. 8, a circuit generating a control signal φ0 includes a level conversion unit 23 and an inverter 24. Inverter 24 receives a memory array select signal x0. The output of inverter 24 is applied to level conversion unit 23 from which a control signal φ0 is output. Level conversion unit 23 includes an inverter 25 corresponding to inverter 14 of level conversion unit 101 in FIG. 2, n channel MOS transistors 26a and 26b corresponding to n channel MOS transistors 15a and 15b, respectively, and p channel MOS transistors 27a and 27b corresponding to p channel MOS transistors 16a and 16b, n channel MOS transistors 26a and 26b and p channel MOS transistors 27a and 27b are connected with node I as node A and node J as node B.
Even if select signal x0 of FIG. 8 is a signal that selects submemory array MA0, leakage occurs in segment boosting signal line SL0 when there is a fault in word drivers DRV0 -DRV225 and in submemory array MA0. In this case, global boosting signal line GL must be disconnected from segment boosted signal line SL0. By blowing out fuse 220, boosted potential VPP of global boosted signal line GL will not be supplied to segment boosted signal line SL0.
Similar to the first embodiment, because high resistor 7 is provided parallel to switching transistor 6 in the present fifth embodiment, a high speed read out can be carried out. Furthermore, because fuse 220 is provided between high resistor 7 and segment boosted signal line SL0, consumed current is reduced as in the first embodiment.
Because a fuse 220 is provided between switching transistor 6 and segment boosted signal line SL0, a fuse 220 corresponding to the exchanged submemory array MA0 in substituting submemory array MA0 with spare memory array SMA should be blown out. As a result, global boosted signal GL can be completely and easily disconnected from segment boosted signal line SL regardless of conduction or nonconduction of switching transistor 6. This separation can be carried out using the circuit that generates control signal φ0 as shown in FIG. 8 since the conduction or nonconduction of switching transistor 6 is not relied upon. Therefore, the circuit can be simplified in comparison with that shown in FIG. 2 of the first embodiment.
FIG. 9 is a block diagram schematically showing a semiconductor memory device according to a sixth embodiment of the present invention. Components differing from those shown in the third embodiment of FIG. 4 and the fifth embodiment of FIG. 7 will be described.
Fuse 18 of the third embodiment of FIG. 4 is removed and a fuse 221 is provided instead as in the embodiment shown in FIG. 7. A series element 223 is formed of high resistor 7 and fuse 8, and a series element 225 is formed of diode circuit 17 and fuse 220. Control signal φ0 applied to the gate electrode of switching transistor 6 is supplied by the circuit for generating control signal φ0 shown in FIG. 8. The present embodiment is characterized in that the effects similar to those of the third embodiment shown in FIG. 4 can be obtained.
More specifically, high resistor 7 is provided parallel to switching transistor 6, and diode circuit 17 is provided between the power supply node and segment boosted signal line SL0. Therefore, a high speed read out can be carried out, and the yield improved.
Also, fuse 8 is provided between high resistor 7 and segment boosted signal line SL0. When the leakage current from segment boosted signal line SL0 is so great that it cannot rise to the level of boosted potential VPP and remains in the vicinity of VCC -Vth when switching transistor 6 attains a non-conductive state, fuse 8 is to be blown out. As a result, the current flowing to segment boosted signal line SL0 from global boosted signal line GL via high resistor 7 is cut off, so that consumed current is reduced.
A fuse 221 is provided between switching transistor 6, high resistance 7 and diode circuit 17 and segment boosted signal line Sl0. Fuse 220 is blown out when the leakage current is so great that the potential of segment boosted signal line falls to the level in the vicinity of ground potential even when charge is supplied to segment boosted signal line SL0 by high resistor 7 and diode circuit 17, or when there is no fault with the word driver and spare memory array SMA is used due to a defective submemory array MA0. This prevents the charge from being supplied to segment boosted signal line SL0 from high resistor 7 and diode circuit 17 in the submemory array that is no longer used. Therefore, consumed current is reduced. The separation between global boosted signal line GL and segment boosted signal line SL0 due to blowing out fuse 220 does not depend upon conduction or nonconduction of switching transistor 6. Therefore, the circuit for generating control signal φ0 is more simple than that of FIG. 2.
FIG. 10 is a circuit diagram of a word driver of a semiconductor memory device according to a seventh embodiment of the present invention. FIG. 11 shows a circuit for generating a boosted decode signal RXik (i=0, 1, . . . , 31, k=0, 1, 2, 3) applied to the word driver of FIG. 10.
Referring to FIG. 10, boosted decode signal RXik is applied to the source of p channel MOS transistor 261. An inversion signal ZWD which is an output of the row decoder is applied to p channel MOS transistor 261, so that word line WL is selected to be raised to the level of boosted potential VPP in combination with boosted decode signal RXik. Although boosted decode signal RXik is generated by a circuit as shown in FIG. 11, the circuit structure includes a level conversion unit 30, an inverter 31, and a NAND gate 32.
Memory array select signal xi and predecode signal XSk are applied to NAND gate 32. The output of NAND gate 32 is applied to inverter 31. The output of inverter 31 is applied to level conversion unit 30. Level conversion unit 30 includes an inverter 33 corresponding to inverter 14 of level conversion unit 101 of FIG. 2, n channel MOS transistors 34a and 34b corresponding to n channel MOS transistors 15a and 15b, and p channel MOS transistors 35a and 35b corresponding to p channel MOS transistors 16a and 16b. n channel MOS transistors 34a and 34b and p channel MOS transistors 35a and 35b are connected with node K as node A and node L as node B. Boosted decode signal RXik applied to the word driver of FIG. 10 is output from node L.
Boosted decode signal RXik is generated on the basis of memory array select signal xi which attains a H level in response to a row address signal and a predecode signal XSk which attains a H level in response to a signal of 2 bits out of the row address signal. When memory array select signals x0, x16 and predecode signal XS0 attain a H level according to an input address signal, and all the other signals attain a L level, boosted decode signal RX0, RX160 attain a level of boosted potential VPP and the other boosted decode signals attain the level of ground potential. As another example, when memory array select signals x1 and x17 and predecode signal XS1 attain a H level and all the other signals attain a L level, boosted decode signals RX11, RX171 attain a level of boosted potential VPP and the other boosted decode signals attain the level of ground potential.
Because the word driver is formed of a CMOS inverter in the present seventh embodiment, it is not necessary to pull up the boosted decode signal to the level of boosted potential VPP after the decode signal from the row decoder is input to transmit the potential of the VPP level to the word line by a self boost. It is therefore not necessary to delay boosted decode signal RXik, so that high speed access can be carried out without delay in the access time period due to increase in the delay time of boosted decode signal RXik. Furthermore, the difficult timing design for determining a delay time of boosted decode signal RXik so that the access time period is not delayed and sufficient self boosting is carried out are no longer required. Therefore, the timing design is simplified. Furthermore, the layout area for a delay circuit to delay boosted decode signal RXik is reduced, so that the chip area can be made smaller.
Furthermore, boosted potential VPP applied to the word driver formed of a CMOS inverter is applied as boosted decode signal RXik from a circuit for generating a boosted decode signal and not from a global boosted signal line as shown in FIG. 26. Therefore, boosted decode signal RXik attains the level of ground potential when a corresponding submemory array is de-selected, whereby the signal line transmitting RXik is disconnected from the global boosted signal line. Therefore, a leakage current via a plurality of word drivers such as in the case where boosted potential VPP is directly applied from a global boosted signal line is not generated, so that consumed current is reduced. The fault of standby current ICC generated due to this leakage current is also suppressed.
Furthermore, it is not necessary to completely decode signal ZWD with a row decoder since decode can be carried out by the word driver itself using signal ZWD from the row decoder and boosted decode signal RXik. Therefore, the circuit complexity of the row decoder is reduced. The pitch of the word lines can be made more narrow to allow increase in the integration density.
FIGS. 12A and 12B are diagrams for describing reduction in the chip area of a row decoder according to the seventh embodiment of FIG. 10. Particularly, FIG. 12A shows the provision of boosted potential VPP from a global boosted signal line to the word driver formed of a CMOS inverter shown in FIG. 26, and FIG. 12B shows the provision of boosted potential VPP to the word driver formed of a CMOS structure of FIG. 10 by a boosted decode signal RXik.
FIGS. 12A and 12B show the case where one out of the eight word lines (WL<0>-WL<7>) are selected. In FIG. 12A, eight input signals WD are required for the eight word drivers. Therefore, the row decoders require eight 3 NAND gates. Furthermore, address signals must be decoded with signals A0-A2, so that 6 address lines are required including inversion signals /A0-/A2. In contrast, in FIG. 12B, only two signals ZWD are required for the eight word drivers from the row decoder. Therefore, only two row decoders are required. Because the row decoder is not a 3 NAND gate, it can be formed by an inverter, and the circuit area required for the row decoder is reduced.
FIG. 13 is a circuit diagram of a word driver of a semiconductor memory device according to an eighth embodiment of the present invention. Only the components differing from those of the embodiment shown in FIG. 10 will be described hereinafter.
Referring to FIG. 13, an n channel MOS transistor 36 is connected parallel to n channel MOS transistor 271 connected to ground potential GND. Also, the gate of n channel MOS transistor 36 is supplied with an inversion signal ZRXik of boosted decode signal RXik.
First, the problems of the embodiments shown in FIG. 10 will be described. When signal ZWD attains a L level (select state) and boosted decode signal RXik attains a L level (de-select state), p channel MOS transistor 261 and n channel MOS transistor 271 both attain an off state, and the word line WL attains a floating state of a L level.
Therefore, by applying inversion signal ZRXik of boosted decode signal RXik to the gate of n channel MOS transistor 36, word line WL can be pulled to the level of ground potential GND at a de-select state. Particularly, when signal ZWD attains a L level (select state) and a boosted decode signal RX attains a L level (de-select state), word line WL attains a de-select state. Therefore, the application of inversion signal ZRXik of a H level (de-select state) to n channel MOS transistor 36 causes n channel MOS transistor 36 to be turned on, whereby word line WL can be pulled down to the level of ground potential GND.
In addition to the effect of the embodiment shown in FIG. 10, the embodiment of FIG. 13 provides the advantage that a floating state of word line WL when boosted decode signal RXik attains a L level (de-select state) can be suppressed, so that damage of data stored in a memory cell caused by a rise in the charge of the word line by noise or the like can be suppressed.
FIG. 14 is a block diagram schematically showing a semiconductor memory device according to a ninth embodiment of the present invention. FIG. 15 shows a circuit generating a control signal φik (i=0, 1, . . . , 31, k=0, 1, 2, 3) of the switching transistor of FIG. 14.
Referring to FIG. 14, semiconductor memory device 41 includes a plurality of submemory arrays MAi (i=0, 1, . . . , 31), a row decoder RDi (i=0, 1, . . . , 31) provided at one side of each submemory array MAi, a word driver group DRVG0 having word drivers DRV0 -DRV255 provided at word lines WL0 -WL255 arranged corresponding to each submemory array MAi, a segment boosted signal line SLik (i=0, 1, . . . , 31, k=0, 1, 2, 3) connected to any of word drivers DRV0 -DRV255, a global boosted signal line GL, a switching transistor connected between global boosted signal line GL and segment boosted signal line SLik, and sense amplifier bands SA0 -SA32.
Each memory array MAi is divided into a plurality of memory cell groups SBMA. For example, memory array MA0 is divided into a memory cell groups SBMA00 corresponding to word lines WL0 -WL63, a memory cell group SBMA01 corresponding to word lines WL64 -WL127, a memory cell group SBMA02 corresponding to word lines WL128 -WL191, and a memory cell group SBMA03 corresponding to word lines WL192 -WL255. Similarly, memory array MA1 is divided into memory cell groups SBMA10, SBMA11, SBMA12 and SBMA13. Memory array MA31 is divided into memory cell groups SBMA310, SBMA311, SBMA312, and SBMA313.
A word driver corresponding to each memory cell group SBMAik is connected to the same segment boosted signal line. For example, word drivers DRV0 -DRV63 corresponding to memory cell group SBMA00 is connected to a segment boosted signal line SL00. Word drivers DRV64 -DRV127 corresponding to memory cell group SBMA01 is connected to segment boosted signal line SL01. Word drivers DRV128 -DRV191 corresponding to memory cell group SBMA02 are connected to a segment boosted signal line SL02. Word drivers DRV192 -DRV255 corresponding to memory cell group SBMA03 are connected to a segment boosted signal line SL03. Switching transistors 42, 43, 44 and 45 are provided between each of segment boosted signal lines SL00, SL01, SL02 and SL03 and global boosted signal line GL.
As shown in FIG. 15, a circuit for generating a control signal φik which is applied to the gate electrode of each switching transistor includes a level conversion unit 46, a 3 NAND gate 47, a fuse 49, and a resistor 48. Fuse 49 is connected between power supply potential VCC and a node O. Resistor 48 is connected between node O and ground potential GND. The output from node O is applied to 3 NAND gate 47. A memory array select signal xi (i=0, 1, . . . , 31) and sub memory array select signal sk (k=0, 1, 2, 3) are applied to the other inputs of 3 NAND gate 47. The output of 3 NAND gate 47 is applied to level conversion unit 46.
Level conversion unit 46 includes an inverter 50 corresponding to inverter 14 of level conversion unit 101 of FIG. 2, n channel MOS transistors 51a and 51b corresponding to n channel MOS transistors 15a and 15b, respectively, and p channel MOS transistors 52a and 52b corresponding to p channel MOS transistors 16a and 16b, respectively. n channel MOS transistors 51a and 51b and p channel MOS transistors 52a and 52b are connected with node M as node A and node N as node B. Thus, control signal φik is output from node N.
When fuse 49 shown in FIG. 15 is not blown out, and sub memory array select signal sk and memory array select signal xi both attain a H level, the output of 3 NAND gate 47 attains a L level. Control signal φik which is the output of level conversion unit 46 is applied to a switching transistor by boosted potential VPP of a H level. As a result, that switching transistor is rendered conductive. When switching transistor 42, for example, is rendered conductive, word drivers DRV0 -DRV63 are driven to select memory cell group SBMA00. Thus, memory array MAi separated by sense amplifier bands SA0 -SA32 is further divided into four regions. Therefore, a sub memory array select signal sk is required.
There are cases when memory cell group SBMA must be exchanged by some reason. Therefore, semiconductor memory device 41 includes a spare memory array SMA, a spare row decoder SRD provided at one side of spare memory array SMA, a word driver group SDRVG having a spare word driver provided at each spare word line corresponding to spare memory array SMA, a spare segment signal boosted line SSLsk (k=0, 1, 2, 3) connected to a spare word driver, switching transistors 53, 54, 55 and 56 connected between global boosted signal line GL and spare segment signal line SSLsk, and spare sense amplifier band SSA.
Spare memory array SMA is divided into spare sub memory cell groups SSBMA0 -SSBMA3 having a memory capacity equal to that of memory cell group SBMAik of memory array MA. When 256 word lines are provided in spare memory array SMA, there are spare memory cell groups SSBMA0, SSBMAi, SSBMA2, and SSBMA3 for every 64 word lines. A word driver corresponding to each of spare memory cell groups SSBMA0 -SSBMA3 is connected to spare segment boosted signal lines SSLs0, SSLs1, SSLs2, and SSLs3. For example, all spare word drivers corresponding to spare memory cell group SSBMA0 is connected to spare segment boosted signal line SSLs0.
Switching transistors 53, 54, 55 and 56 are provided between each of spare segment boosted signal lines SSLs0, SSL01, SSLs2, and SSLs3 and global boosted signal line GL. Control signal φsi applied to the gate electrode of each of switching transistors 53, 54, 55 and 56 is a control signal corresponding to a memory cell group SBMAik to be exchanged.
In order to use spare memory cell group SSBMA, fuse 49 of FIG. 15 corresponding to memory cell group SBMAik to be exchanged is blown out. This blow out of fuse 49 causes the output of 3 NAND gate 47 to be pulled up to a H level and control signal φik to a L level regardless of the level of sub memory array select signal sk and memory array select signal xi. Control signal φik is applied to a switching transistor corresponding to the to-be-exchanged sub memory array SBMAik to be turned off. As a result, memory cell group SBMAik is not used, and spare memory cell group SSBMA is used instead.
Because the word drivers belonging to memory array MA divided by sense amplifier band SA are not all connected to the same segment boosted signal line, the VPP generation circuit not shown does not have to provide boosted voltage VPP as long as control signal φ00 does not render conductive switching transistor 49 even when leakage occurs is segment voltage signal line SL00. As a result, consumed current is suppressed. Even in the case of a sub threshold leakage or junction leakage instead of leakage in segment boosted signal line SLik, the generation is limited only in the transistor belonging to the selected segment boosted signal line. Therefore, the leakage current is suppressed in comparison with the case where the word drivers are connected to the same segment boosted signal line.
Because spare memory array SMA is divided by spare memory cell group SSBMAk, it is not necessary to carry out exchange at the unit of memory arrays. Exchange of one memory cell group SBMA is carried out with a spare memory cell group SSBMA, so that the exchange efficiency is improved. Furthermore, because it is not necessarily required to divide spare memory array SMA into a plurality of spare memory cell groups SSBMA, the chip area can be suppressed.
More specifically, in the present seventh embodiment, four segment boosted signal lines are provided for one memory array, wherein each memory array is divided into four memory cell groups according to word lines connected to a switching transistor corresponding to each segment boosted signal line. Therefore, a spare memory cell group can be substituted at a memory cell group unit that is smaller than the unit of the first embodiment in which a spare memory array is substituted for a memory array. Therefore, the exchange efficiency can be improved in comparison with that of the first embodiment with the same spare memory array size. For example, when each first memory cell group is defective in the first and second memory arrays, the semiconductor memory device will become defective in the first embodiment because the second memory array cannot be substituted since there is only one spare memory array. In contrast, the seventh embodiment can have the two defective memory cell groups substituted with two spare memory cell groups. Therefore, this semiconductor memory device can be repaired.
If the chip area must be reduced, the number of the spare memory cell groups should be reduced although the exchange efficiency will be degraded. The exchange efficiency and chip area depends upon how many portions a memory array is divided into, and how many spare memory cell groups are provided. Selection is to be carried out for an optimum value from the standpoint of exchange efficiency and chip area.
In the semiconductor memory device of FIG. 14, word lines are locally fixed depending on to which of the four segment boosted signal lines it corresponds to, and in which of the four memory cell groups it is included. Alternatively, word lines may be disposed so that every fourth word lines are included in the same memory cell groups as in the case where word lines WL0, WL4, WL8, . . . are included in one memory cell group, word lines WL1, WL5, WL9 are included in another memory cell group, and so on.
FIG. 16 is a block diagram Schematically showing a semiconductor memory device according to a tenth embodiment of the present invention. FIG. 17 shows a circuit for generating a control signal φik (i=0, 1, . . . , 31, k=0, 1, 2, 3) of a switching transistor. Only the components differing from those of the ninth embodiment shown in FIGS. 14 and 15 will be described hereinafter.
In the present tenth embodiment, a fuse is provided in each segment boosted signal line SLik (i=0, 1, . . . , 31, k=0, 1, 2, 3) to disconnect global boosted signal line GL from segment boosted signal line SLik. For example, fuses 57, 58, 59 and 60 are provided in segment boosted signal lines SL00, SL01, SL02, and SL03, respectively, connected to switching transistors 42, 43, 44 and 45, respectively. Each of fuses 57, 58, 59 and 60 carry out a function corresponding to fuse 49 of FIG. 15. Also, instead of 3 NAND gate 47 of FIG. 15, NAND gate 300 of FIG. 17 receives sub memory array select signals Sk and memory array select signal xi. Control signal φik controlling a switching transistor is generated by the circuit shown in FIG. 17.
A fuse corresponding to a memory cell group SBMAik (i=0, 1, . . . , 31, k=0, 1, 2, 3) to be exchanged is blown out, and exchange is carried out by a spare cell group SSBMA.
In the present tenth embodiment, the word drivers belonging to a submemory array are not all connected to the same segment boosted signal line. Therefore, the VPP generation circuit not shown does not operate to pull up the leaking segment boosted signal line to the level of boosted voltage VPP as long as the switching transistor that raises the one segment boosted signal line to the level of boosted potential is not rendered conductive when one of the four segment boosted signal lines shows leakage. Therefore, consumed current is suppressed. Furthermore, the sub threshold leakage or junction leakage is limited to be generated only in the transistor belonging to the selected segment boosted signal line. Thus, leakage current is suppressed in comparison with the case where all the word drivers are connected to the same segment boosted signal line. Furthermore, the exchange efficiency is improved and the chip are is reduced in comparison with the case of the first embodiment shown in FIG. 1.
Each of fuses 57, 58, 59 and 60 operate in a manner similar to that of fuse 220 of the fifth embodiment of FIG. 7. More specifically, each of fuses 57, 58, 59 and 60 are connected between switching transistors 42, 43, 44 and 45 and segment boosted signal lines SL00, SL01, SL02, and SL03, respectively. By blowing out a fuse corresponding to a memory cell group to be exchanged, a global boosted signal line can be completely and easily disconnected from a segment boosted signal line regardless of the conduction or nonconduction of that switching transistor. Furthermore, such a disconnection eliminates the need of a circuit for generating a control signal φik that is shown in FIG. 15. Only a simple circuit as that shown in FIG. 17 is required.
An eleventh embodiment will be described hereinafter.
In the ninth embodiment shown in FIG. 14, a switching transistor is provided corresponding to each memory cell group SBMA and spare memory cell group SSBMA. It is considered that the embodiments shown in FIGS. 1-6 may be applied to a switching transistor. The present eleventh embodiment is an application of the fourth embodiment of FIG. 5 to the switching transistor provided corresponding to each memory cell group SBMA and spare memory cell group SSBMA in the ninth embodiment shown in FIG. 14.
The first embodiment shown in FIG. 1, the second embodiment shown in FIG. 3, the third embodiment shown in FIG. 4, and the fourth embodiment shown in FIG. 5 relate to the provision of a predetermined potential between a boosted potential and the ground potential to a word driver. By applying such an embodiment to the ninth embodiment of FIG. 14, a semiconductor memory device is provided that carries out an operation at a higher speed. In this case, not only access of high speed, but also leakage from a segment boosted signal line can be slightly compensated for according to the embodiment of FIG. 5. Therefore, the memory cell group belonging to the segment boosted signal line compensated for the leakage does not have to be exchanged by a spare memory cell group. Therefore, the exchange efficiency is improved.
The chip area is as described in the ninth embodiment of FIG. 4. It may be considered that the chip area for the provision of each switching transistor in the circuit of FIG. 5 is increased. However, the chip area is greater for the spare memory cell group in comparison with a memory cell group corresponding to the circuit shown in FIG. 5. Therefore, it can be considered that the chip area is eventually reduced.
Thus, by applying the fourth embodiment of FIG. 5 into the ninth embodiment of FIG. 14, reduction in consumed current and the chip area, and also improvement in the exchange efficiency and access rate can be achieved.
FIG. 18 is a block diagram schematically showing a semiconductor memory device according to a twelfth embodiment of the present invention. FIG. 19 shows a circuit for generating a boosted decode signal RXik (i=0, 1, . . . , 31, k=0, 1, 2, 3). In the following, components differing from those shown in the ninth embodiment of FIG. 14 and the circuit shown in FIG. 11 will be described.
Referring to FIG. 18, a boosted decode signal RXik (i=0, 1, . . . , 31, k=0, 1, 2, 3) is used instead of boosted potential VPP, switching transistors 42, 43, 44 and 45, and control signal φik in FIG. 14. In comparison with the embodiment shown in FIG. 14 where each group of 64 word lines is connected to the same segment boosted signal line, the present twelfth embodiment has every fourth word lines arranged in the same memory cell group. For example, word lines WL0, WL4, WL8, . . . are included in one memory cell group, and word lines WL1, WL5, WL9, . . . are included in another memory cell group. Therefore, one memory array includes four memory cell groups. This means that the concept of a memory cell group is not one that is divided substantially as that shown in FIG. 14, and corresponds to a more higher concept level.
The output signals of row decoder RD0 are not the 252 signals of /WD0 -WD255, but 63 signals of/WD0 -/WD63. More specifically, the same signal of /WD0 is applied to word drivers DRV0 -DRV3 provided in word lines WL0 -RL3, respectively. For word drivers DRV252 -DRV255 provided in word lines WL252 -WL255, respectively, the same signal of /WD63 is applied. Word drivers DRV0 -DRV255 are word drivers shown in the seventh embodiment of FIG. 10.
Word drivers DRV0 -DRV255 are set as a word driver group DRVG0. A word driver group DRVGi (i=1, 2, . . . , 31) is provided with respect to another memory array MAi (i=1, 2, . . . , 31). Similarly, spare memory array SMA is divided into four spare memory cell groups. A spare row decoder SRD and a spare word driver group SDRVG are also provided. Boosted decode signals SRX0, SRX1, SRX2, and SRX3 are applied to spare word driver group SDRVG.
In order to exchange the spare memory cell group of spare memory array SMA with the memory cell group of submemory array MA, a fuse 301 and a resistor 303 as shown in FIG. 19 are provided with respect to the circuit generating boosted decode signal RXik of FIG. 11. Fuse 301 is connected between power supply potential VCC and a node P. Resistor 303 is connected between ground potential GND and node P. By blowing out fuse 301 regardless of the level of predecode signal xsk and memory array select signal xi, boosted decode signal RXik is fixed at a L level. Therefore, the word line of a memory cell group belonging to boosted decode signal RXik fixed to a L level is not activated. The no-longer used memory cell group is exchanged with a spare memory cell group.
In the present embodiment, the memory array is divided into sub memory arrays, and the spare memory array is divided into spare sub memory arrays. Therefore, effects identical to those of the ninth embodiment of FIG. 14 and the tenth embodiment of FIG. 16 can be obtained regarding the exchange efficiency and chip area.
Furthermore, because a word driver according to the seventh embodiment shown in FIG. 10 is used as a word driver, high speed access is possible on account of reduction of the circuit complexity of the row decoder and boosted decode signal RXik that does not have to be delayed.
FIG. 20 is a block diagram schematically showing a semiconductor memory device according to a thirteenth embodiment of the present invention. Components differing from those of the twelfth embodiment of FIG. 18 will be described.
A fuse is provided at each segment boosted signal line SLik (i=0, 1, . . . , 31, k=0, 1, 2, 3) shown in FIG. 19. More specifically, a fuse 305 is provided at segment boosted signal line SL00, a fuse 307 is provided at segment boosted signal line SL01, a fuse 309 is provided at segment boosted signal line SL02, and a fuse 311 is provided at segment boosted signal line SL03. These fuses 305, 307, 309 and 311 carry out a function identical to that of fuse 301 of FIG. 19. The effects of the present thirteenth embodiment are similar to those of the twelfth embodiment of FIG. 18. In addition, the circuit for generating boosted decode signal RXik is simplified as that shown in FIG. 11. Therefore, the circuit structure is further simplified.
The word driver of the thirteenth embodiment of FIG. 13 may be applied to a semiconductor memory device of FIGS. 18 and 20. In this case, the effects such as reduction in the chip area of a space memory and a row decoder, improvement in the exchange efficiency and access rate, suppression of floating, and reduction of consumed current can be achieved.
Although the present invention has been described and illustrated in detail, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, the spirit and scope of the present invention being limited only by the terms of the appended claims.
Hidaka, Hideto, Arimoto, Kazutami, Tomishima, Shigeki
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