Source: https://patents.google.com/patent/JP4684394B2/en
Timestamp: 2019-12-05 16:02:13
Document Index: 743490383

Matched Legal Cases: ['Art 1', 'Art 3', 'Art 4', 'Art 6', 'Art 7', 'Art 8', 'Art 9', 'arts 1', 'Art 1', 'arts 2', 'Art 4', 'Art 5', 'Art 6', 'art 7', 'Art 8', 'art 9', 'arts 1', 'art, 1']

JP4684394B2 - Semiconductor integrated circuit device - Google Patents
JP4684394B2
JP4684394B2 JP2000204288A JP2000204288A JP4684394B2 JP 4684394 B2 JP4684394 B2 JP 4684394B2 JP 2000204288 A JP2000204288 A JP 2000204288A JP 2000204288 A JP2000204288 A JP 2000204288A JP 4684394 B2 JP4684394 B2 JP 4684394B2
JP2000204288A
JP2002025265A (en
2000-07-05 Application filed by エルピーダメモリ株式会社 filed Critical エルピーダメモリ株式会社
2000-07-05 Priority to JP2000204288A priority Critical patent/JP4684394B2/en
2002-01-25 Publication of JP2002025265A publication Critical patent/JP2002025265A/en
2011-05-18 Publication of JP4684394B2 publication Critical patent/JP4684394B2/en
The present invention relates to a semiconductor integrated circuit device and, for example, relates to a technique that is effective for use in a large-capacity semiconductor memory device that requires high-speed read operation.
As a result of research after the present invention is considered to be related to the present invention to be described later, JP-A-10-340579 (hereinafter referred to as Prior Art 1), JP-A-11-39871 (hereinafter referred to as JP-A-11-39871) Japanese Patent Laid-Open No. 10-334659 (hereinafter referred to as Prior Art 3), Japanese Patent Laid-Open No. 9-198873 (hereinafter referred to as Prior Art 4), Japanese Patent Laid-Open No. 7-282833 (hereinafter referred to as Prior Art). No. 5), JP-A-4-162286 (hereinafter referred to as Prior Art 6), JP-A-7-272479 (hereinafter referred to as Prior Art 7), JP-A-7-272248 (hereinafter referred to as Prior Art 8). ) And JP-A-11-16361 (hereinafter referred to as Prior Art 9).
In the context of the present invention, the prior arts 1 to 9 are outlined as follows. In Prior Art 1, when even data is output first, the operation timing of the odd and even data bus amplifiers is shifted. In the prior arts 2 and 3, the operation timing of the read buffer in the previous stage of the read register is pipelined for each bank. In Prior Art 4, the operation timing of the sense amplifier in the previous stage of the output latch is shifted according to the column. In Prior Art 5, the operation timing of the sense amplifier in the previous stage of the output latch is shifted. In Prior Art 6, the amplifiers in the previous stage of the output latch are operated alternately. In the prior art 7, the operation timing of the column switch in the previous stage of the output latch is pipelined. In Prior Art 8, the operation timing of the data detection circuit in the previous stage of the output latch is shifted according to the address. In the prior art 9, the driving capabilities of the sense amplifiers in the previous stage of the latch are made different. In the prior arts 1 to 9, there is no description that suggests the necessity of realizing high speed in the prefetch operation with a simple configuration as in the present invention described later.
DDR SDRAM (Double Data Rate Synchronous Dynamic Random Access Memory; hereinafter simply referred to as DDR SDRAM) performs data input / output at both edges of the clock. Therefore, when operated at a clock frequency of 200 MHz, a data transfer rate of 400 Mbps, which is twice as high, can be obtained. If DDR is taken with a chip configuration similar to that of an SDRAM, the inside of the chip must be moved at twice the frequency, but this cannot be realized with the same device. Therefore, in the DDR SDRAM, by prefetching, the operating frequency in the chip is made equal to that of the SDRAM, and only data input / output is speeded up to realize 400 Mbps. Therefore, in the DDR SDRAM, the data transfer system from the main amplifier to the output buffer is greatly different from that in the SDRAM.
In the SDRAM, it is considered that about 20% of the consumption current ICC is the charge / discharge current of the global input / output line GIO which is the data transfer line to the main amplifier-output buffer. For this reason, peak current is becoming a problem when the prefetch operation is performed. In other words, when data input / output is performed in 16-bit units, 32 main units of 2 times the SDRAM in the 2 N prefetch operation and 64 main amplifiers 4 times the 4 times in the 4N prefetch operation and the corresponding global input / output line GIO are provided. Peak current is an important issue because it operates simultaneously. If a technique for increasing the speed of the main amplifier circuit and the global input / output line GIO is used in order to improve the performance, there arises a problem that the peak current further increases.
SUMMARY OF THE INVENTION An object of the present invention is to provide a semiconductor integrated circuit device including a signal transmission circuit which has a simple configuration and is capable of increasing the speed of data input / output and improving the operation margin. Another object of the present invention is to provide a semiconductor integrated circuit device including a semiconductor memory circuit that realizes area saving and power saving in addition to high speed and improvement of operation margin. The above and other objects and novel features of the present invention will be apparent from the description of this specification and the accompanying drawings.
The outline of a typical invention among the inventions disclosed in the present application will be briefly described as follows. The first and second data are transferred in parallel by the first signal transmission path, amplified by the first and second relay amplifier circuits, and passed through the second signal transmission path. In parallel An output circuit for transmitting to the first and second output registers and serially outputting the first and second data respectively held in the first and second output registers based on the address information; In the first and second relay amplifier circuits, the second signal of the other data to be output later with respect to one of the first and second data to be output first Delay the output timing to the transmission path.
The outline of other representative ones of the inventions disclosed in the present application will be briefly described as follows. First and second data are transferred in parallel by the first signal transmission path, amplified by the first and second relay amplifier circuits, and the first and second output registers are transmitted through the second signal transmission path. An output circuit for serially outputting the first and second data held in the first and second output registers based on the address information, respectively. A relay amplifier circuit is provided with a selection circuit so that one of the first and second data to be output first corresponds to the first output register, and the other data to be output later is the first data. 2, the transmission speed on the second signal transmission path corresponding to the first output register is the transmission speed on the second signal transmission path corresponding to the second output register. Be faster.
FIG. 1 shows an overall block diagram of an embodiment of a DDR SDRAM according to the present invention. The control input signals are a row address strobe signal / RAS, a column address strobe signal / CAS, a write enable signal / WE, and an output enable signal / OE. Here, / corresponds to an overbar of a logical symbol where the low level represents the active level. The X address signal and the Y address signal are input in time series from the common address terminal Add in synchronization with the clock signals CK and / CK.
The X address signal and the Y address signal input through the address buffer are respectively taken into the latch circuits. The X address signal taken into the latch circuit is supplied by the predecoder, and the output signal is supplied to the X decoder to form a selection signal for the word line WL. By the word line selection operation, a minute read signal appears on the complementary bit line BL of the memory array, and the amplification operation is performed by the sense amplifier. The Y address signal taken into the latch circuit is supplied to the predecoder, and its output signal is supplied to the Y decoder to form a selection signal for the bit line BL. The X relief circuit and the Y relief circuit compare the storage operation of the defective address with the stored defective address and the captured address signal, and if they match, select the spare word line or bit line to select the X decoder and Y decoder. And the selection operation of the normal word line or the normal bit line is prohibited.
The stored information amplified by the sense amplifier is selected by a column switch circuit (not shown) and connected to the common input / output line and transmitted to the main amplifier. The main amplifier is not particularly limited, but a writing circuit is also provided. That is, during the read operation, the read signal read through the Y switch circuit is amplified and output from the external terminal DQ through the output buffer. In the write operation, the write signal input from the external terminal DQ is taken in via the input buffer and transmitted to the common input / output line and the selected bit line via the write circuit, and the sense amplifier amplifies the selected bit line. A write signal is transmitted by the operation, and a charge corresponding to the signal is held in the capacitor of the memory cell.
The clock generation circuit (main control circuit) is configured to take in an address signal input control timing signal corresponding to the clock signals CK and / CK and the signals / RAS and / CAS, an operation timing signal of the sense amplifier, and the like. Various timing signals necessary for the memory cell selection operation are generated. The internal power supply generation circuit receives operating voltages such as Vcc and Vss supplied from the power supply terminals, and receives the plate voltage, precharge voltage such as Vcc / 2, internal boosted voltage VCH, internal buck voltage VDL, and substrate back bias. Various internal voltages such as voltage VBB are generated. The refresh counter generates a refresh address signal when the riff mode is set, and is used for an X-system selection operation.
FIG. 2 is a block diagram showing the entire configuration of an embodiment of a DDR SDRAM according to the present invention. In the SDRAM of this embodiment, the chip is divided into eight as a whole so as to constitute a plurality of memory blocks or banks. Each block divided into eight has the same configuration. An X decoder XDC is provided along one end of the memory array, and a Y decoder YDC and a main amplifier MA are arranged near the chip center in a direction perpendicular to the X decoder XDC. The eight memory blocks are arranged in a vertically symmetrical manner so that two of them form one set and the X decoder XDC is adjacent to each other, thereby forming one memory bank as described above. The two memory banks each including two sets of memory blocks are also symmetrically arranged in the figure. Further, the Y decoder YDC and the main amplifier MA are arranged symmetrically so as to be adjacent to each other around a peripheral circuit provided at the longitudinal center of the chip.
The memory array portion of one memory block includes an array divided into a plurality along the word lines extending in the vertical direction in the figure from the X decoder XDC, and the plurality of sub word lines provided in each array. A hierarchical word line system is employed in which the main word line is arranged so as to penetrate the array and the sub word line selection line is selected. Thereby, the number of memory cells connected to the sub word line is reduced, and the sub word line selection operation is speeded up.
The memory block has an array divided into a plurality along a Y selection line extending from the Y decoder YDC, and a bit line is divided for each array. As a result, the number of memory cells connected to the bit line is reduced, and a signal voltage read from the memory cell to the bit line is ensured. The memory cell is composed of a dynamic memory cell, and corresponds to information 1 and 0 indicating whether or not the storage capacitor has a charge. By the charge coupling between the charge of the storage capacitor and the precharge charge of the bit line. Since a read operation is performed, a necessary signal amount can be ensured by reducing the number of memory cells connected to the bit line.
Sub-word driver columns are arranged above and below the divided array, and sense amplifier columns are arranged on the left and right sides (bit line direction) of the array. The sense amplifier column is provided with a column selection circuit, a bit line precharge circuit, and the like, and a minute potential difference that appears on each bit line by reading data from a memory cell by selecting a word line (sub word line) is detected by the sense amplifier. Detect and amplify.
A main input / output line MIO, which will be described later, is not particularly limited, but extends in the horizontal direction in FIG. A local input / output line LIO is arranged along the sense amplifier row, and the local input / output line LIO and the main input / output line MIO are connected by a row selection signal. The peripheral input / output line GIO is arranged in the peripheral circuit, and is connected to the main input / output line MIO corresponding to the selected memory bank. The global input / output line MIO is connected to a pad DQPAD connected to an external terminal through the output buffer and the input buffer through an input / output register.
Although not shown, peripheral circuits as will be described below are appropriately provided in the center of the chip. The address signal supplied from the address input terminal is taken into the row address buffer circuit and the column address buffer in the address multiplex format. Each address buffer holds the supplied address signal. For example, the row address buffer and the column address buffer respectively hold the captured address signal for one memory cycle period. At the center of the chip, a relief circuit made up of a fuse and a MOSFET for address comparison is also provided.
The row address buffer takes in the refresh address signal output from the refresh control circuit as a row address signal in the refresh operation mode. In this embodiment, the refresh address signal is fetched as a row address signal through a clock generation circuit, although not particularly limited. The address signal taken into the column address buffer is supplied as preset data to a column address counter included in the control circuit. The column address counter outputs a column address signal as the preset data or a value obtained by sequentially incrementing the column address signal to the Y decoder YDC in accordance with an operation mode designated by a command to be described later.
The control circuit is not particularly limited, but includes external control signals such as a clock signal, a clock enable signal, a chip select signal, a column address strobe signal, a row address strobe signal, a write enable signal, a data input / output mask control signal, and a memory bank Address signals corresponding to the DDR SDRAM are formed, and various control signals such as an operation mode of the DDR SDRAM and various timing signals corresponding to the control signals are formed on the basis of the level change and timing of those signals. A mode register is provided.
FIG. 3 shows a schematic overall configuration diagram of a DDR SDRAM according to the present invention. This figure corresponds to FIG. 2, and the memory array is divided into eight chips as a whole. In the figure, four memory arrays of half of them are shown as representative examples, and an enlarged view of a part related to the present invention is shown in the other half of the drawings. An X decoder XDC is provided along one end of the memory array, and a Y decoder YDC and a main amplifier MA are arranged near the center of the chip in a direction perpendicular to the X decoder XDC. The eight memory arrays are provided in a vertically symmetrical manner with two as one set with the X decoder XDC interposed therebetween. Thus, one memory bank (Bank 2) is constituted by two memory arrays provided with the X decoder XDC interposed therebetween. The other memory bank (Bank 3) is also composed of two memory arrays similar to the above.
One memory array is provided with an array divided into a plurality along the word lines extending in the vertical direction from the X decoder XDC in FIG. A hierarchical word line system is adopted in which the sub word lines provided in each of the arrays are selected by a sub word driver by a main word line arranged so as to penetrate the plurality of arrays and a sub word line selection line. Similarly, the memory array has an array divided into a plurality along the Y selection line extending from the Y decoder YDC, and the bit line is divided by each of the arrays.
The bit lines are divided by sense amplifier rows provided at both ends thereof, and local input / output lines LIO are provided along the bit line rows. The local input / output line LIO is connected to the main input / output line MIO via a selection circuit selected by a row address. The main output line MIO will be described by taking a memory bank (Bank2) shown as an example as a representative example. In the memory array divided into two, 16 pairs (pairs) are parallel to the Y selection line. Are extended along the sub-word driver string. Therefore, in one memory bank (Bank2), 32 pairs (pairs) of main input / output lines MIO are provided. 32 main amplifiers MA are provided corresponding to these 32 pairs of main input / output lines MIO.
Output signals of the 32 main amplifiers MA are supplied to 32 pairs of global input / output lines GIO extending in the vertical direction of the chip. These global input / output lines GIO extend the vertical direction of the chip so as to be connected to main amplifiers MA provided corresponding to two memory banks (Bank0, Bank2) provided in the lower half of the chip (not shown). Formed.
A peripheral circuit is provided at the center of the chip. In the drawing, an output system circuit related to the present invention among the above peripheral circuits is exemplarily shown as a representative. The peripheral circuit is provided with a row address buffer circuit, a column address buffer circuit, and the like that take in an address signal supplied from an address input terminal (not shown) in an address multiplex format. The output system circuit includes an output buffer DQ0-15 and an amplifier circuit AMP provided in the preceding stage. The output buffers DQ0-15 perform data output in parallel in units of 16 bits. 32 amplifier circuits Amp are provided corresponding to the global input / output lines GIO, and a selection circuit (FIFO) is provided in the output section thereof, so that 16-bit signals corresponding to odd addresses or 16 addresses corresponding to even addresses are provided. The bit signal is transmitted to the 16 output buffers DQ0-15.
In the DDR SDRAM of this embodiment, the main input / output line MIO is divided into an odd address (ODD Add) and an even address (EVEN Add) in the two memory arrays of the one memory bank (Bank 2). 2N (N is 16 here) prefetch that selects 32 bits in total from each memory array corresponding to the column address signal and outputs 32 bits of data using the global input / output line GIO. Perform the action. Then, the output circuit outputs 16 bits of the head address in synchronization with the rising edge of the clock signal CK and the remaining 16 bits of data in synchronization with the falling edge of the clock signal.
Although not particularly limited, the embodiment of FIG. 2 or 3 is directed to a DDR SDRAM having a large storage capacity such as about 256 Mbits. The chip is divided into eight memory blocks, and two blocks form one bank. One memory block is divided into an 8 × 16 array (submat), and one submat is 512 × 512 bits. That is, 512 memory cells are connected to one sub-word line, and 512 memory cells are connected to the bit line. In the following description, the main input / output line MIO is abbreviated as MIO line using the circuit symbol MIO, and the global input / output line GIO is abbreviated as GIO line using the circuit symbol GIO.
In this embodiment, a main amplifier circuit, a main amplifier output circuit, a GIO line, and an output register circuit are allocated for ODD / EVEN addresses, respectively. As described above, data transfer from the main amplifier to the output register is performed simultaneously with ODD / EVEN. That is, the 32-bit data read to the MIO line is simultaneously sensed by the main amplifier circuit and transferred to the output register in parallel. In response to the ODD / EVEN of the start address, the data in the output register is output in synchronization with the rise and fall of the clock. Therefore, in this embodiment, 32 main amplifier circuits and 32 GIO lines operate simultaneously.
FIG. 4 shows a block diagram of an embodiment of a read system circuit of the DDR SDRAM according to the present invention. This embodiment is directed to the 2N prefetch operation as described above. That is, in order to reduce the peak current when the 32-bit data read to the MIO line is simultaneously sensed by the main amplifier circuit and transferred to the output register in parallel through the GIO line, the data transferred by the GIO line. Are output with the timing shifted between the 1st output data and the 2nd output data.
The configuration includes 16 main amplifiers, their amplifier output circuits, GIO lines, and output registers corresponding to the input / output terminals DQ0 to DQ15 for odd (ODD) data and even (EVEN) data. The amplifier output circuit is provided with an MA control circuit for adjusting the output timing, and the ODD (or EVEN) data to be output first corresponding to the start address information is directly transmitted to the output register through the GIO line. Then, EVEN (or ODD) data to be output later is delayed by the MA control circuit and transmitted to the output register through the GIO line. That is, the control circuit of the main amplifier is controlled separately for ODD and EVEN, and the 1st output data (clock rising) is directly output to the GIO line according to the start address, and the 2nd output data (clock falling) The data is output to the GIO line with a delay.
For example, at the time of ODD start, a memory cell is selected corresponding to both addresses of ODD / EVEN, and data is read to the sense amplifier, LIO and MIO by the first clock signal CLK and is taken into the main amplifier MA. As described above, in the case of ODD start, 1st data corresponding to ODD data is transferred to the output register through the GIO line as it is as the output signal of the main amplifier. Next, 2nd data corresponding to the EVEN data is delayed and transferred to the output register.
If EVEN start is instructed at the next clock, the memory cell is selected correspondingly to both addresses of ODD / EVEN, and data is read to the sense amplifier, LIO and MIO by the second clock signal CLK. Import into MA. As described above, in the case of the EVEN start, the 1st data corresponding to the EVEN data is transferred to the output register as it is through the output signal of the main amplifier through the GIO line. Next, the 2nd data corresponding to the ODD data is delayed and transferred to the output register.
Although not particularly limited, 0 of the ODD data addressed first is output at the rising edge of the third clock CLK, and 1 of EVEN data read at the same time is output at the falling edge of the clock signal. At the rising edge of the fourth clock CLK, 2 of the second addressed EVEN data is output, and at the same time, 3 of the ODD data read out is output at the falling edge of the clock signal. Thereafter, similar memory cell selection operation, data transfer and output operation are performed in a pipeline manner in response to the clock signal CLK.
In this embodiment, in the 2N prefetch DDR SDRAM as described above, it is possible to reduce the number of GIO lines that are charged and discharged simultaneously from 32 to 16. In addition, a 4N prefetch DDR SDRAM can also be configured by a similar method, and in that case, the number of GIO lines that are simultaneously charged and discharged can be reduced from 64 to 16. Since the 2nd output data has a margin in half clock time, the performance of the data output operation does not deteriorate even if the transfer timing on the GIO line is delayed.
FIG. 5 shows a circuit diagram of an embodiment of a main amplifier used in the DDR SDRAM according to the present invention. In this embodiment, a pair of main amplifiers corresponding to the 2N prefetch, a main amplifier output circuit, and a control circuit thereof are exemplarily shown as representatives. The ODD side circuit of the pair of ODD / EVEN circuits will be specifically described below. The main amplifier circuit takes in the signals of the pair of main input / output lines MIOT and MIOB through the P-channel type MOSFETs Q1 and Q2 which are turned on by the low level of the timing signal DMAPSB.
The captured signal includes P-channel MOSFETs Q3 and Q4 and N-channel MOSFETs Q5 and Q6 whose gates and drains are cross-connected, a commonly connected source of the N-channel MOSFETs Q5 and Q6, and a circuit ground potential. Is amplified by a CMOS latch circuit composed of an N-channel MOSFET Q7 for supplying an operating current. That is, when the timing signal DMAPSB is taken in during a low level and the desired signal amount is secured, the timing signal DMAPSB goes high, and the main input / output lines MIOT and MIOB and the latch circuit The input / output terminal is separated, and the latch circuit starts an amplifying operation in response to the high level of the timing signal DAMAET. At this time, since the MIO line having a large parasitic capacitance is separated, the CMOS latch circuit amplifies the signal transmitted through the MIO line to the CMOS level at a high speed and holds it by the latch circuit composed of the gate circuits G4 and G5. Let
The main amplifier output circuit transmits the output signal of the main amplifier circuit to an output circuit composed of a P-channel output MOSFET Q8 and an N-channel output MOSFET Q9 through gate circuits G6 and G7 controlled by a timing signal DMOET (ODD). An output signal DGOUT0 transmitted to the GIO line is formed by current amplification of the output signal taken into the main amplifier circuit.
This circuit example is characterized in that the main amplifier control circuit controls the timing of the main amplifier output signal by the start address signal (STARTADD). That is, in the case of ODD start, STARTADD = L (low level), and the gate circuit G1 opens the gate of the clock signal DRCLK and the gate circuits G1 and G2 that selectively transmit the delay signal to the main clock signal DRCLK. Since it is transmitted to the amplifier output circuit, the ODD data is output first in synchronization with the clock signal DRCLK.
On the other hand, in the main amplifier control circuit on the EVEN side, the gate circuit corresponding to the gate circuit G2 opens the gate contrary to the ODD side, and transmits the delay signal to the main amplifier output circuit on the EVEN side. The EVEN data is delayed by a delay time set in a delay circuit provided in the main amplifier control circuit. In the case of EVEN start, the reverse operation is performed. As described above, the main amplifier control circuit switches the output timing of the main amplifier corresponding to the start address, that is, the transfer timing of the ODD and EVEN data transmitted through the GIO line, so that the start address is arbitrary. The address selection circuit of the memory cell and the transmission path of the read signal can be made uniform.
FIG. 6 is a waveform diagram for explaining an example of the operation of the main amplifier circuit of FIG. After the main amplifier is activated (timing signal DMAET), the timing of the main amplifier output signal (timing signal DMOET) to the GIO line is controlled so that one of ODD or EVEN comes first and the other comes after the start address. Therefore, the peak current can be reduced by shifting the charging / discharging timing of the GIO line, that is, the output signal DGIOT0 (ODD) and the output signal DGIOT1 (EVEN).
FIG. 7 shows a circuit diagram of an embodiment of the output circuit. The output circuit of this embodiment includes an output register and an output buffer circuit. In this embodiment, a through latch (T-Latch) circuit is used as the output register circuit. This circuit outputs through data during the high level period of the clock signals CLK1 and CLK2, and latches it at the low level of the clock signals CLK1 and CLK2. The output buffer circuit is configured by using a two-input through latch circuit (T-Latch) and a buffer circuit (Dout Buff.). This circuit selects ODD data or EVEN data for data to be output through according to the start address, and outputs the data in synchronization with the clock. This circuit is an embodiment, and it is possible to perform the same circuit operation using another circuit.
FIG. 8 is a block diagram showing another embodiment of the read circuit of the DDR SDRAM according to the present invention. This embodiment is directed to 4 N prefetch. In the case of 4N prefetch, the 4 bits of the lower address (0 to 3) are simultaneously read from the memory cell to the MIO line and simultaneously sensed by the main amplifier. Therefore, in this embodiment, a main amplifier control circuit is provided for each lower address, and control is performed by shifting the output timing to the GIO line according to the start address.
For example, when the start address is 0, address 0 data is output first, and thereafter, the timing is shifted in accordance with the order in which the address advances (0 → 1 → 2 → 3 in the case of sequential). When the start address is 1, the data of address 1 is output first, and then the data is output with the timing shifted in accordance with the order in which the address advances (that is, 1 → 2 → 3 → 0 in the case of sequential). Therefore, in this configuration, since the main amplifier control circuit is provided for each lower address, it is possible to obtain the above-described effect of the present method without depending on the start address.
FIG. 9 is a block diagram showing another embodiment of the read system circuit of the DDR SDRAM according to the present invention. This embodiment is directed to 2N prefetch. In this embodiment, the main amplifier output circuit, the GIO line, and the output register circuit are not assigned to ODD / EVEN as in the embodiment of FIG. 4, but are transferred for 1st output and 2nd output. A signal transmission path to be used is allocated in accordance with the timing of data. That is, up to the main amplifier, a switching circuit for switching which GIO line to output data in accordance with the start address when 32 bits are read simultaneously and output to the GIO line is provided in the input part of the amplifier output circuit.
In this embodiment, the even number (0, 2,... 30) of the GIO line is assigned for 1st output and the odd number (1, 3... 31) is assigned for 2nd output. Therefore, in the case of ODD start, the data of the ODD main amplifier is output to the even GIO line, and the data of the EVEN main amplifier is output to the odd GIO line. Similarly, in the case of EVEN start, the data of the EVEN main amplifier is output to the even GIO line, and the data of the ODD main amplifier is output to the odd GIO line. According to this embodiment, no address information is required in the output register, and output timing control is facilitated.
FIG. 10 is a circuit diagram showing another embodiment of the main amplifier used in the DDR SDRAM according to the present invention. In this embodiment, a pair of main amplifier, switching circuit, main amplifier output circuit and control circuit thereof in the embodiment of FIG. 9 are shown as examples. The main amplifier circuit and the main amplifier output circuit are the same as those in the embodiment of FIG.
The switching circuit is provided between the main amplifier circuit and the main amplifier output circuit, and transmits the output of the ODD main amplifier circuit to either the 1st main amplifier output circuit or the 2nd main amplifier output circuit. And a CMOS switch circuit for transmitting the output of the EVEN main amplifier circuit to either the 1st main amplifier output circuit or the 2nd main amplifier output circuit.
When the output of the ODD main amplifier circuit is transmitted to the 1st main amplifier output circuit, the pair of CMOS switch circuits transmits the output of the EVEN main amplifier circuit to the 2nd main amplifier output circuit, and conversely, the ODD main amplifier circuit. When the output of the amplifier circuit is transmitted to the 2nd main amplifier output circuit, the output of the EVEN main amplifier circuit is transmitted to the 1st main amplifier output circuit, and each of the main amplifier output circuits 1st and 2nd uses the ODD Data and EVEN data are prevented from colliding with each other.
As described above, the circuit of this embodiment is characterized in that the main amplifier output circuit and the GIO line are assigned for 1st output and 2nd output, and the amplification result of the main amplifier is switched by the start address and output. That is, in the case of ODD start, STARTADD = L (low level), and the main amplifier circuit for ODD is connected to the first main amplifier output circuit by the control signal formed by the main amplifier control circuit, and the main amplifier circuit for EVEN is 2nd. Connect to the main amplifier output circuit. On the other hand, in the case of EVEN start, the connection is made in the reverse manner.
FIG. 11 is a waveform diagram for explaining an example of the operation of the main amplifier circuit of FIG. A switching circuit (selector) is provided between the main amplifier circuit and the main amplifier output circuit to control which GIO line is output based on the start address information. Therefore, in the case of ODD start, ODD data is output to the 1st GIO line (DGIOT0), and EVEN data is output to the 2nd GIO line (DGIOT1). On the other hand, the reverse is true for EVEN start.
FIG. 12 is a block diagram showing another embodiment of the read system circuit of the DDR SDRAM according to the present invention. This embodiment is an application example of the embodiment shown in FIG. 11 and is characterized by speeding up the 1st GIO line. That is, the signal transmission speed-up method is applied to the 1st GIO line, and the 2nd GIO line uses a normal signal transmission line.
As a method for speeding up the GIO line, (a) the pitch of the GIO line is relaxed. For example, wiring resistance and capacitance are reduced by doubling L / S. (B) GIO wiring read / write separation. Usually, read / write is common to reduce the number of wires, but the load is reduced by separating them. (C) Small amplitude signal transfer is performed on the GIO line. For example, a small amplitude interface such as GTL or SSTL is adopted. With this method, the access time can be shortened by speeding up the 1st GIO line as an access bus. With this configuration, the circuit scale can be reduced to half as compared with a configuration that speeds up all GIO lines.
FIG. 13 shows a pattern diagram of an embodiment of the GIO line. In this embodiment, an example of increasing the speed by changing the wiring pitch of the GIO lines is shown. The GIO line for the 1st output data has a GIO line width of 3 times the normal (1.5 μm) to reduce the wiring resistance, and the GIO line for the 2nd output data is 0.5 μm. In order to reduce the wiring capacity, it is possible to increase the width between the lines.
FIG. 14 is a block diagram showing another embodiment of the read circuit of the DDR SDRAM according to the present invention. This embodiment is a modification of the embodiment of FIG. 12 and is characterized in that it is assigned to 1st and 2nd including the main amplifier circuit. That is, the ODD / EVEN data of the MIO line is switched according to the start address, input to the main amplifier, and amplified / output. At this time, a high-speed main amplifier circuit is applied to the 1st main amplifier. That is, a circuit that prioritizes high-speed operation is used. The 2nd main amplifier uses a different normal circuit. In other words, a circuit that prioritizes reduction of operating current is used.
Examples of the high-speed main amplifier circuit include (a) a static main amplifier circuit. Normally, a dynamic main amplifier circuit is used to reduce the operating current. However, the speed can be increased by using a static type. (B) A two-phase drive main amplifier circuit is used. With this circuit, the access time can be shortened by speeding up the 1st GIO line as an access bus.
FIG. 15 shows a configuration diagram of an embodiment of the main amplifier used in the embodiment of FIG. As a high-speed main amplifier, a static type amplifier is used as shown in (A), and a dynamic type amplifier is used as a normal amplifier as shown in (B). This dynamic amplifier is the same as the main amplifier circuit shown in FIGS. Here, since the (A) static amplifier does not require a timing margin for securing a signal amount, the delay time Td until the output signals OUT and / OUT are obtained is shortened and the speed is high. Since the operation current continues to flow during the operation period in which the signal EN is at the high level, the current consumption is large.
On the other hand, since the dynamic amplifier (B) requires a timing margin Tm until a desired signal amount is obtained, the delay time Td until the output signals OUT and / OUT as described above are obtained increases. However, if the amplified output becomes large, either the latch-type P-channel MOSFET or the N-channel MOSFET is turned off, and the operating current does not flow, so the current consumption is small. Therefore, by properly using the main amplifier as in this embodiment, the high-speed amplifier is applied only to the access path to increase the effective operation speed, and the normal path is used for the other paths to reduce power consumption. It is feasible.
FIG. 16 is a block diagram showing another embodiment of the read circuit of the DDR SDRAM according to the present invention. In this embodiment, a modification of 2N prefetch is shown. This embodiment is characterized in that the data transfer to the 2nd GIO line is delayed by a delay. That is, the data transfer to the 1st GIO line is output in the same manner as in the embodiment of FIG. 12, and the data transfer to the 2nd GIO line is delayed by the delay as in the embodiment of FIG. To do. This makes it possible to obtain the same effect as that of the embodiment of FIG. 4 and also to delay the data transfer to the 2nd GIO line so that the timing of the next cycle data can be relaxed.
FIG. 17 is a block diagram showing another embodiment of the read system circuit of the DDR SDRAM according to the present invention. This embodiment is a modification of the embodiment of FIG. 16, and is directed to 4 N prefetch. Similarly, in the case of 4 N prefetch, 4 bits (when N is 1) are simultaneously sensed by the main amplifier, and then output to the 1st GIO to 4th GIO lines in the order of output corresponding to the lower address. In this embodiment, the main amplifier control circuit is prepared separately for 1st to 4th, but for example, 1st and 2nd may be shared and output at every 2 bits.
FIG. 18 is a layout diagram showing one embodiment of the GIO line of the DDR SDRAM according to the present invention. The GIO line arrangement example of this embodiment is characterized in that the first GIO line and the 2nd GIO line are alternately laid out in the embodiment of FIG. That is, in the chip configuration example of FIG. 2, 32 pairs of GIO lines that run a long distance on the chip are alternately arranged for 1st and 2nd.
With this configuration, when the 1st GIO line is charged / discharged, the 2nd GIO line does not operate (the timing is shifted), and the 2nd GIO line serves as a shield line. Therefore, the 1st GIO line can be transferred at high speed. In the embodiment of FIG. 4, the same effect can be obtained by alternately laying out the ODD and EVEN GIO lines in the same manner.
FIG. 19 is a block diagram showing an embodiment of a DDR SDRAM write system circuit according to the present invention. Since the signal transmission direction of the write circuit is opposite to that of the read circuit, the signal transmission may be reversed in each of the embodiments. In the control of the GIO line data transfer from the write system input buffer to the main amplifier, the same control as in the read system is performed for the 1st input data and 2nd input data input serially.
For example, both ODD / EVEN data is input to the input register and then not output to the GIO line, but the first input data is transferred to the GIO line first to reduce the peak current by shifting the timing. To do. In the write circuit, 2nd input data (clock falling) is worst in terms of timing, so control is performed to give priority to 2nd. That is, since the 2nd input data is transmitted to the write amplifier through the GIO line and then written in parallel to the 2N memory cells through the ODD and EVEN MIO lines together with the previously transferred 1st input data. Input data (clock falling) has no time margin in terms of timing.
Therefore, in this embodiment, the GIO line for transferring the 2nd input data is a high-speed GIO line, and the main amplifier and the write amplifier are also used for the high-speed amplifier, thereby controlling the 2nd input data with priority. It is. As a result, it is possible to increase the speed in the writing system circuit, and it is possible to realize a reduction in peak current by shifting the timing by transferring to the GIO line.
FIG. 20 is a block diagram showing an embodiment of a dynamic RAM to which the present invention is applied. The dynamic RAM in this embodiment is directed to a DDR SDRAM. Although the DDR SDRAM of this embodiment is not particularly limited, four memory cell arrays 200A to 200D are provided corresponding to four memory banks as in the above embodiment. The memory cell arrays 200A to 200D respectively corresponding to the four memory banks 0 to 3 are provided with dynamic memory cells arranged in a matrix, and according to the figure, the selection terminals of the memory cells arranged in the same column are the word for each column. Data input / output terminals of memory cells coupled to a line (not shown) and arranged in the same row are coupled to a complementary data line (not shown) for each row.
One word line (not shown) of the memory cell array 200A is driven to a selected level according to the decoding result of the row address signal by the row decoder (Row DEC) 201A. Complementary data lines (not shown) of the memory cell array 200A are coupled to I / O lines of a sense amplifier (Sense AMP) 202A and a column selection circuit (Column DEC) 203A. The sense amplifier 202A is an amplifier circuit that detects and amplifies a minute potential difference appearing on each complementary data line by reading data from the memory cell. In this case, the column selection circuit 203A includes a switch circuit for selecting the complementary data lines individually and conducting them to the complementary I / O lines. The column switch circuit is selectively operated according to the decoding result of the column address signal by the column decoder 203A.
Similarly, the memory cell arrays 200B to 200D are provided with row decoders 201B to 201D, sense amplifiers 203B to 203D, and column selection circuits 203B to 203D. A complementary I / O line of each memory bank is a data input circuit (Din Buffer) having a write buffer in which each memory bank is shared via a data bus constituting the global input / output line GIO. The output terminal 210 is connected to the input terminal of the data output circuit (Dout Buffer) 211. The terminal DQ is not particularly limited, but is a data input / output terminal that inputs or outputs 16-bit data D0 to D15. A DQS buffer (DQS Buffer) 215 forms a data strobe signal for data output from the terminal DQ during a read operation.
Address signals A0 to A14 supplied from address input terminals are temporarily held in an address buffer 204, and among the address signals input in time series, a row address signal is a row address buffer (Row Address buffer). The column address signal is held in a column address buffer 206. A refresh counter 208 generates a row address at the time of automatic refresh (automatic refresh) and self refresh (self refresh).
For example, when having a storage capacity of 256 Mbits, an address terminal for inputting an address signal A14 is provided as a column address signal when memory access is performed in units of 2 bits. In the x4 bit configuration, the address signal A11 is valid, in the x8 bit configuration, the address signal A10 is valid, and in the x16 bit configuration, the address signal A9 is valid. In the case of a storage capacity of 64 Mbits, the address signal A10 is valid in the x4 bit configuration, the address signal A9 is valid in the x8 bit configuration, and in the x16 bit configuration as shown in the figure. Up to the address signal A8 is valid.
The output of the column address buffer 206 is supplied as preset data of a column address counter 207, and the column address counter 207 is a column as the preset data in a burst mode specified by a command to be described later. An address signal or a value obtained by sequentially incrementing the column address signal is output to the column decoders 203A to 203D.
A mode register (Mode Register) 213 holds various operation mode information. Of the row decoders 201A to 201D, only those corresponding to the bank designated by the bank select circuit 212 operate, and the word line selection operation is performed. The control circuit (Control Logic) 209 is not particularly limited, but includes clock signals CLK and / CLK (the symbol / indicates a bar signal indicating that a signal to which the signal is attached is a low enable signal), a clock. External control signals such as enable signal CKE, chip select signal / CS, column address strobe signal / CAS, row address strobe signal / RAS, and write enable signal / WE, and address signals via / DM and DQS and mode register 213 And an internal timing signal for controlling the operation mode of the DDR SDRAM and the operation of the circuit block based on the change in the level of the signal, the timing, etc., and the input corresponding to each signal. Provide a buffer.
Clock signals CLK and / CLK are input to DLL circuit 214 via a clock buffer, and an internal clock is generated. The internal clock is not particularly limited, but is used as an input signal for the data output circuit 211 and the DQS buffer 215. The clock signal via the clock buffer is supplied to the data input circuit 210 and a clock terminal supplied to the column address counter 207.
Other external input signals are made significant in synchronization with the rising edge of the internal clock signal. The chip select signal / CS instructs the start of the command input cycle according to its low level. When the chip select signal / CS is at a high level (chip non-selected state) or other inputs are meaningless. However, internal operations such as a memory bank selection state and a burst operation, which will be described later, are not affected by the change to the chip non-selection state. Each of the signals / RAS, / CAS, / WE has a function different from that of a corresponding signal in a normal DRAM, and is a significant signal when defining a command cycle to be described later.
The clock enable signal CKE is a signal that indicates the validity of the next clock signal. The rising edge of the next clock signal CLK is valid if the signal CKE is high level, and invalid when the signal CKE is low level. In the read mode, when the external control signal / OE for controlling the output enable for the data output circuit 211 is provided, the signal / OE is also supplied to the control circuit 209. When the signal is at a high level, for example. The data output circuit 211 is set to a high output impedance state.
The row address signal is defined by the levels of A0 to A11 in a later-described row address strobe / bank active command cycle synchronized with the rising edge of the clock signal CLK (internal clock signal).
The address signals A12 and A13 are regarded as bank selection signals in the row address strobe / bank active command cycle. That is, one of the four memory banks 0 to 3 is selected by a combination of A12 and A13. The selection control of the memory bank is not particularly limited, but only the row decoder on the selected memory bank side is activated, all the column switch circuits on the non-selected memory bank side are not selected, the data input circuit 210 and the data only on the selected memory bank side This can be done by processing such as connection to an output circuit.
When the column address signal is 256 M bits and × 16 bits as described above, a read or write command synchronized with the rising edge of the clock signal CLK (internal clock) (column address / read command, column address described later) Write command) Defined by the levels of A0 to A9 in the cycle. The column address thus defined is used as a burst access start address.
In a DDR SDRAM, when a burst operation is performed in one memory bank, if another memory bank is specified in the middle and a row address strobe / bank active command is supplied, The row address operation in another memory bank can be performed without affecting the operation in the memory bank.
Therefore, for example, when data D0 to D15 do not collide at a 16-bit data input / output terminal, during execution of a command that has not been processed, the command being executed is different from the memory bank to be processed. It is possible to start the internal operation in advance by issuing a precharge command and a row address strobe / bank active command. The DDR SDRAM of this embodiment performs memory access in units of 16 bits as described above, and has about 4M addresses by the addresses A0 to A11, and is composed of four memory banks. The storage capacity is 256M bits (4M × 4 banks × 16 bits).
The detailed read operation of the DDR SDRAM is as follows. Chip select / CS, / RAS, / CAS, and write enable / WE signals are input in synchronization with the CLK signal. At the same time as / RAS = 0, a row address and a bank selection signal are input and held in the row address buffer 205 and the bank select circuit 212, respectively. The row decoder 210 of the bank designated by the bank select circuit 212 decodes the row address signal, and the data of the entire row is output from the memory cell array 200 as a minute signal. The output minute signal is amplified and held by the sense amplifier 202. The specified bank becomes active.
After 3 CLK from the row address input, a column address and a bank selection signal are input simultaneously with CAS = 0, and are held in the column address buffer 206 and the bank select circuit 212, respectively. If the designated bank is active, the held column address is output from the column address counter 207, and the column decoder 203 selects a column. The selected data is output from the sense amplifier 202. The data output at this time is two sets (8 bits in the x4 bit configuration, 32 bits in the x16 bit configuration).
Data output from the sense amplifier 202 is output from the data output circuit 211 to the outside of the chip via the LIO-MIO and the main amplifier and the data bus DataBus as described above. The output timing is synchronized with both rising and falling edges of QCLK output from the DLL 214. At this time, as described above, two sets of data composed of ODD and EVEN are converted from parallel to serial to become one set × 2 data. Simultaneously with the data output, a data strobe signal DQS is output from the DQS buffer 215. When the burst length stored in the mode register 213 is 4 or more, the column address counter 207 automatically increments the address and reads the next column data.
The role of the DLL 214 is to generate an operation clock for the data output circuit 211 and the DQS buffer 215. The data output circuit 211 and the DQS buffer 215 take time until the data signal and the data strobe signal are actually output after the internal clock signal generated by the DLL 214 is input. For this reason, the phase of the internal clock signal is advanced from that of the external CLK by using an appropriate replica circuit, so that the phase of the data signal or the data strobe signal is matched with that of the external clock CLK. Therefore, the DQS buffer is set to an output high impedance state during a time other than the data output operation as described above.
During the write operation, since the DQS buffer 215 of the DDR SDRAM is in an output high impedance state, a data strobe signal DQS is input to the terminal DQS from a data processor such as a macro processor, and the terminal DQ is synchronized with it. Written data is input. The data input circuit 210 receives the write data input from the terminal DQ serially as described above by the clock signal formed based on the data strobe signal input from the terminal DQS, and synchronizes with the clock signal CLK. Then, the data is converted into parallel data, transmitted to the selected memory bank via the data bus DataBus, and written to the selected memory cell in the memory bank.
By applying the present invention to the DDR SDRAM as described above, a semiconductor memory capable of high-speed writing and reading can be configured while reducing the size of the memory chip.
The effects obtained from the above embodiment are as follows.
(1) The first and second data are transferred in parallel by the first signal transmission path, amplified by the first and second relay amplifier circuits, and the first and second data are transmitted through the second signal transmission path. And an output circuit for serially outputting the first and second data held in the first and second output registers based on the address information, respectively. In the second relay amplifier circuit, for one of the first and second data to be output first, output of the other data to be output later to the second signal transmission path By delaying the timing, it is possible to reduce the peak current consumption during parallel data transfer. In addition to improving the operating margin while maintaining high speed, it is possible to achieve area and power savings. An effect is obtained.
(2) In addition to the above, by serially outputting the first and second data corresponding to both the rising edge and falling edge of the clock signal, the operating frequency of the internal circuit is doubled. There is an effect that data can be output at a high speed.
(3) First and second data are transferred in parallel by the first signal transmission path, amplified by the first and second relay amplifier circuits, and first and second are transmitted through the second signal transmission path. And an output circuit for serially outputting the first and second data held in the first and second output registers based on the address information, respectively. A selection circuit is provided in the second relay amplifier circuit so that one of the first and second data to be output first corresponds to the first output register, and the other data to be output later As a result, the operation of the output circuit can be simplified.
(4) In addition to the above, by serially outputting the first and second data corresponding to both the rising edge and falling edge of the clock signal, the operating frequency of the internal circuit is doubled. There is an effect that data can be output at a high speed.
(5) In addition to the above, the first and second amplifier circuits and the second relay that take in the first data and the second data transmitted through the first signal transmission path through the first and second relay amplifier circuits. The amplifying circuit includes third and fourth amplifying circuits that amplify an output signal to be transmitted to the second signal transmission path, and the selection circuit includes the output terminals of the first and second amplifying circuits and the third amplifying circuit. Between the first amplifier and the input terminal of the fourth amplifier circuit, one of the data to be output first corresponds to the first output register, and the other data to be output later is stored in the second output register. The effect of simplifying the operation of the output circuit can be obtained with a simple configuration of corresponding.
(6) In addition to the above, the first signal line of the second signal transmission path corresponding to the first output register and the third amplifier circuit for driving the first signal line may correspond to the second output register. In addition to improving the operating margin while simplifying and speeding up the operation of the output circuit by making the signal transmission speed faster than the second signal line of the second signal transmission path and the fourth amplifier circuit that drives the second signal line. As a result, the area and power saving can be realized.
(7) In addition to the above, the first and second amplifier circuits and the second relay that take in the first data and the second data transmitted through the first signal transmission path through the first and second relay amplifier circuits. The amplifying circuit includes third and fourth amplifying circuits that amplify an output signal to be transmitted to the second signal transmission path, and the selection circuit includes the output terminals of the first and second amplifying circuits and the third amplifying circuit. Between the first amplifier and the input terminal of the fourth amplifier circuit, one of the data to be output first corresponds to the first output register, and the other data to be output later is stored in the second output register. In addition to improving the operating margin while achieving a high speed with a simple configuration of making it correspond, an effect of realizing area saving and power saving can be obtained.
(8) In addition to the above, the first signal line of the second signal transmission path corresponding to the first output register, the third amplifier circuit driving the first signal line, and the first amplifier circuit are included. By further increasing the signal transmission speed of the second signal line of the second signal transmission path corresponding to the two-output register, the fourth amplifier circuit driving the second signal line, and the second amplifier circuit, the speed can be further increased. The effect that it can plan is acquired.
(9) In addition to the above, the first signal line of the second signal transmission path is very simple because the wiring resistance value can be reduced by forming the wiring width larger than that of the second signal line. The effect that speed can be achieved with a simple configuration is obtained.
(10) In addition to the above, by delaying the output timing of the second relay amplifier circuit to the second signal line with respect to the output timing of the first relay amplifier circuit to the first signal line, The peak current at the time of signal transfer can be reduced, and the operation margin can be improved.
(11) In addition to the above, at least two memory cell array regions are further provided in the first direction of the semiconductor chip and in the second direction orthogonal to the semiconductor chip to form a memory bank, which is configured by a hierarchical word line method and a hierarchical IO method. By applying to a semiconductor memory device comprising a memory array, it is possible to achieve an increase in the speed of the read operation.
(12) In addition to the above, by using a dynamic memory cell, there is an effect that a memory circuit having a small area and a large storage capacity can be obtained.
(13) In addition to the above, the second signal transmission path, the first and second output registers, and the output circuit are provided along the central portion of the semiconductor chip in the first direction or the second direction. By doing so, it is possible to obtain an effect that signals can be transmitted almost uniformly from each memory array (memory bank).
(14) In addition to the above, an input circuit is further provided to transmit the third and fourth data input serially to the relay amplifier circuit through the second signal transmission path, and the fourth data input later is By transmitting through one signal line, an effect that high-speed data input can be achieved is obtained.
(15) In addition to the above, at least two memory cell array regions are further provided in the first direction of the semiconductor chip and in the second direction orthogonal to the semiconductor chip to form a memory bank, which is configured by a hierarchical word line method and a hierarchical IO method. By applying the present invention to a semiconductor memory device comprising a memory array, an effect that the writing operation can be speeded up can be obtained.
The invention made by the inventor has been specifically described based on the embodiments. However, the invention of the present application is not limited to the embodiments, and various modifications can be made without departing from the scope of the invention. Nor. For example, the first and second signal transmission paths and the relay amplifier circuit are circuit blocks incorporated in the system LSI in addition to the read system circuit and the write system circuit including the main amplifier provided in the DDR SDRAM as described above. Similarly, it can be used for signal transmission paths between the block and between the block and the outside.
The memory circuit may be non-volatile using a ferroelectric capacitor as a storage means, in addition to the memory circuit using the dynamic memory cell as described above. Alternatively, it may be a non-volatile memory cell that accumulates charges in a floating gate. The present invention can be widely used in various semiconductor integrated circuit devices that include a relay amplifier circuit and perform data input / output by parallel-serial operation or prefetch operation.
The effects obtained by the representative ones of the inventions disclosed in the present application will be briefly described as follows. First and second data are transferred in parallel by the first signal transmission path, amplified by the first and second relay amplifier circuits, and the first and second output registers are transmitted through the second signal transmission path. An output circuit for serially outputting the first and second data held in the first and second output registers based on the address information, respectively. In the relay amplifier circuit, the output timing of the other data to be output later to the second signal transmission path is delayed with respect to one of the first and second data to be output first. As a result, the peak of the current consumption during parallel data transfer can be reduced, and in addition to improving the operating margin while maintaining high speed, it is possible to realize area and power savings.
First and second data are transferred in parallel by the first signal transmission path, amplified by the first and second relay amplifier circuits, and the first and second output registers are transmitted through the second signal transmission path. An output circuit for serially outputting the first and second data held in the first and second output registers based on the address information, respectively. A relay amplifier circuit is provided with a selection circuit so that one of the first and second data to be output first corresponds to the first output register, and the other data to be output later is the first data. 2, the transmission speed on the second signal transmission path corresponding to the first output register is the transmission speed on the second signal transmission path corresponding to the second output register. Faster than It can be realized in addition to the improvement of the operating margin while achieving simplification and acceleration of the operation of the circuit area saving, power saving.
FIG. 1 is an overall block diagram showing an embodiment of a DDR SDRAM according to the present invention.
FIG. 2 is an overall chip configuration diagram showing an embodiment of a DDR SDRAM according to the present invention;
FIG. 3 is a schematic overall configuration diagram showing an embodiment of a DDR SDRAM according to the present invention.
FIG. 4 is a block diagram showing an embodiment of a read circuit of the DDR SDRAM according to the present invention.
FIG. 5 is a circuit diagram showing one embodiment of a main amplifier used in a DDR SDRAM according to the present invention.
6 is a waveform diagram for explaining an example of the operation of the main amplifier circuit of FIG. 5; FIG.
FIG. 7 is a circuit diagram showing an embodiment of an output circuit used in the DDR SDRAM according to the present invention.
FIG. 8 is a block diagram showing another embodiment of the read system circuit of the DDR SDRAM according to the present invention.
FIG. 9 is a block diagram showing another embodiment of a read system circuit of a DDR SDRAM according to the present invention.
FIG. 10 is a circuit diagram showing another embodiment of the main amplifier used in the DDR SDRAM according to the present invention.
11 is a waveform diagram for explaining an example of the operation of the main amplifier circuit of FIG. 10;
FIG. 12 is a block diagram showing another embodiment of the read system circuit of the DDR SDRAM according to the present invention.
FIG. 13 is a pattern diagram showing an embodiment of a GIO line used in the DDR SDRAM according to the present invention.
FIG. 14 is a block diagram showing another embodiment of a read system circuit of a DDR SDRAM according to the present invention.
15 is a block diagram showing an embodiment of the main amplifier of FIG.
FIG. 16 is a block diagram showing another embodiment of the read system circuit of the DDR SDRAM according to the present invention.
FIG. 17 is a block diagram showing another embodiment of the read system circuit of the DDR SDRAM according to the present invention.
FIG. 18 is a layout view showing one embodiment of a GIO line provided in a DDR SDRAM according to the present invention.
FIG. 19 is a block diagram showing an embodiment of a write system circuit of a DDR SDRAM according to the present invention.
FIG. 20 is a block diagram showing an embodiment of a dynamic RAM to which the present invention is applied.
Q1-Q9 ... MOSFET, G1-G7 ... Gate circuit, N1, N2 ... Inverter circuit,
Bank 1 to 4 ... memory bank, XDC ... X decoder, YDC ... Y decoder,
LIO ... Local I / O line, MIO ... Main I / O line, GIO ... Global I / O line, MA ... Main amplifier,
200A to D ... Memory cell array, 201A to D ... Row decoder, 202A to D ... Sense amplifier, 203A to D ... Column decoder, 204 ... Address buffer, 205 ... Row address buffer, 206 ... Column address buffer, 207 ... Column address counter 208 ... Refresh counter 209 ... Control circuit 210 ... Data input circuit 211 ... Data output circuit 212 ... Bank select circuit 213 ... Mode register 214 ... DLL 214 ... DQS buffer
A first signal transmission path for transferring the first and second data in parallel;
First and second relay amplifier circuits for receiving the first and second data transmitted through the first signal transmission path, respectively;
A second signal transmission path for transferring the first and second data amplified by the first and second relay amplifier circuits in parallel;
First and second output registers for receiving the first and second data transmitted through the second signal transmission path, respectively;
An output circuit for serially outputting the first and second data respectively held in the first and second output registers based on address information;
The first and second relay amplifier circuits may transmit the second signal transmission of the other data to be output later with respect to one of the first and second data to be output first. A semiconductor integrated circuit device characterized by delaying output timing to a path.
The semiconductor integrated circuit device according to claim 1, wherein the first and second data are serially output corresponding to both a rising edge and a falling edge of a clock signal.
Further, the first and second relay amplifier circuits are
Of the first and second data transmitted through the first signal transmission path, one data to be output first corresponds to the first output register, and the other data to be output later is A semiconductor integrated circuit device comprising: a selection circuit for selecting a signal transmission path so as to correspond to the second output register.
Each of the first and second relay amplifier circuits includes:
First and second amplifier circuits for capturing first data and second data transmitted through the first signal transmission path, respectively;
A third and a fourth amplifier circuit for respectively amplifying output signals to be transmitted to the second signal transmission path;
The selection circuit is
Provided between the output terminals of the first and second amplifier circuits and the input terminals of the third and fourth amplifier circuits;
A first operation for transmitting the first data to the third amplifier circuit based on the address information and transmitting the second data to the fourth amplifier circuit;
And a second operation of transmitting the first data to the fourth amplifier circuit and transmitting the second data to the third amplifier circuit.
The first signal line and the third amplifying circuit for driving the one of the first corresponding to the output register the said second signal pathway,
And characterized in that to increase the signal transmission speed than the second signal line and the fourth amplifying circuit for driving the one of the second output corresponding to the said second signal transmission path to the register A semiconductor integrated circuit device.
A third and a fourth amplifier circuit for amplifying output signals to be transmitted to the second signal transmission path, respectively;
The selection circuit is provided between the first signal transmission path and the input terminals of the first and second amplifier circuits,
Based on the address information, the first data is transmitted to the first amplifier circuit, the second data is transmitted to the second amplifier circuit, and the first data is transmitted to the second amplifier circuit. And a second operation of transmitting the second data to the first amplifier circuit.
The first signal line of the second signal transmission path corresponding to the first output register, the third amplifier circuit and the first amplifier circuit for driving the first signal line,
Of the second signal transmission path corresponding to the second output register, the second signal line, the fourth amplifier circuit for driving the signal line, and the signal transmission speed faster than the second amplifier circuit. A semiconductor integrated circuit device.
9. The semiconductor integrated circuit device according to claim 7, wherein the first signal line of the second signal transmission path is formed to have a wiring width larger than that of the second signal line. .
In any of claims 5 to 9,
The output timing to the second signal line by the second relay amplifier circuit is delayed with respect to the output timing to the first signal line by the first relay amplifier circuit. A semiconductor integrated circuit device.
At least two memory cell array regions are further provided in the first direction of the semiconductor chip and in the second direction orthogonal thereto,
Each of the memory cell array regions
Provided corresponding to the plurality of bit lines provided along the first direction, the plurality of word lines provided along the second direction, and the intersections of the plurality of bit lines and the plurality of word lines. A plurality of memory cells, and a plurality of memory array regions arranged along each of the first direction and the second direction;
A plurality of sense amplifier regions arranged alternately with the plurality of memory array regions arranged along the first direction;
A first common input / output line provided in the sense amplifier region and connected to the corresponding bit line through a first selection circuit;
A plurality of first common input / output lines corresponding to a plurality of memory array regions arranged along the first direction and a second common input / output line connected through a second selection circuit;
A first selection signal generating circuit for supplying a selection signal to the plurality of first selection circuits corresponding to the plurality of memory array regions arranged along the first direction;
A second selection signal generating circuit for forming a selection signal for the word lines of the plurality of memory array regions arranged along the second direction,
The second common input / output line constitutes the first signal transmission path, and outputs the first and second data in parallel to the first and second relay amplifier circuits.
A semiconductor integrated circuit characterized in that the second signal transmission path , the first and second output registers, and the output circuit are provided in common to the four memory cell array regions. apparatus.
The memory cell includes a MOSFET and a capacitor, the gate of the MOSFET being a selection terminal, one source and drain being input / output terminals, and the other source and drain being one electrode of the capacitor. A semiconductor integrated circuit device comprising a dynamic memory cell connected to the semiconductor memory device.
The second signal transmission path, the first and second output registers, and the output circuit are provided along a central portion in the first direction or the second direction of the semiconductor chip. Semiconductor integrated circuit device.
An input circuit; and first and second input registers ;
The third and fourth data serially input through the input circuit are the first and second relay amplifier circuits through which the third data input first passes through the first input register and the second signal line. The fourth data input later is transmitted to and held in either one of the first and second relay amplifier circuits through the second register and the first signal line. The semiconductor integrated circuit device is characterized in that the third and fourth data held in the first and second relay amplifier circuits are transmitted in parallel to the first signal transmission path, respectively.
Each of the memory cell array regions includes a plurality of bit lines provided along the first direction, a plurality of word lines provided along the second direction, the plurality of bit lines, and the plurality of word lines. A plurality of memory cells provided corresponding to the intersections of the memory cells, and a plurality of memory array regions arranged along each of the first direction and the second direction;
A plurality of first common input / output lines corresponding to the plurality of memory array regions arranged along the first direction and a second common input / output line connected through a second selection circuit;
In common corresponding to the four memory cell array region, and the upper Symbol second signal transmission path, the first and the second output register, and the output circuit, and the first and second input registers, A semiconductor integrated circuit device comprising the input circuit.
JP2000204288A 2000-07-05 2000-07-05 Semiconductor integrated circuit device Active JP4684394B2 (en)
JP2000204288A JP4684394B2 (en) 2000-07-05 2000-07-05 Semiconductor integrated circuit device
TW90113385A TW508800B (en) 2000-07-05 2001-06-01 Semiconductor integrated circuit device
KR1020010039605A KR20020004860A (en) 2000-07-05 2001-07-03 A semiconductor integrated device
US09/897,997 US6512719B2 (en) 2000-07-05 2001-07-05 Semiconductor memory device capable of outputting and inputting data at high speed
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JP2000204288A Active JP4684394B2 (en) 2000-07-05 2000-07-05 Semiconductor integrated circuit device
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