KR100340071B1 - DDR synchronous memory device accomplishing high speed write operation - Google Patents

Abstract

The present invention uses a column start signal by selecting a signal input later among the upper and lower data strobe signals (uds and lds) to have a fast write access time during a write operation of a DDR synchronous memory. The present invention relates to a light control device for detecting a pulse input generated at a falling edge of an upper data strobe signal and a pulse signal generated at a falling edge of a lower data strobe signal. And a light column controller for outputting a light column signal.

Description

DDR synchronous memory device accomplishing high speed write operation

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to semiconductor memory devices, and more particularly, to a synchronous (DDR) synchronous memory device having a write control device that implements a fast write access time during a write operation.

Generally, the write operation characteristic of DDR synchronous memory shows that data is input after a write command, and the data strobe signal is synchronized with the rising and falling edges of the data strobe signal by controlling the input buffer to which write data is input. Write data is input. The data strobe signal is input through a data strobe buffer and output as an internal control signal. The data strobe signal is synchronized with a rising edge of the data strobe signal and a pulse generated in synchronization with the falling edge of the data strobe signal. It is divided into falling edge data strobe signal generated by. In addition, since the input / output data pad DQ is divided into the upper data pad UDQ and the lower data pad LDQ, the data strobe signal is also divided into the upper data strobe signal UDS and the lower data strobe signal LDS.

1 is a block diagram showing a path for writing data to a cell block of the prior art.

Referring to FIG. 1, the conventional write method includes a data input path and a column path. The pulse signals uds_f, uds_r, lds_f, and lds_r received from the data strobe buffer by receiving the input data Din are input. The data input buffer 100 buffers the data signal in synchronization with the rising and falling edges of the data drop, and the falling of the data strobe signal among the pulse signals output from the data strobe buffer by receiving the data signal output from the data input buffer 100. A first data input unit 110 for aligning the data signal output from the data input buffer 100 to the falling edge of the data strobe signal in synchronization with the pulse signals uds_f and lds_f generated by the edge; The output signal of the data input unit 110 is input and output from the first data input unit 100 to the clock signal clkp4 output from the delay locked loop. A second data input unit 120 for aligning a call and a data input path circuit unit 130 for receiving an output signal of the second data input unit 120 and transferring the input signal to the cell block 170, The control buffer 140 receives the write command outputted from the command decoder and outputs an internal write control signal, and the signal output from the control buffer 140 raises the clock signal clkp4. And a cas signal generator 150 that generates a write column signal casp6_wt in synchronization with the falling edge, and a light column signal casp6_wt that is an output of the cas signal generator, and receives a column line selection signal into the cell block 170. a column path circuit unit 160 for transmitting yi, a write data signal din from the data input path circuit unit 130, and a column line selection signal yi from the column path circuit unit 160 to receive data. To me It includes the cell blocks 170.

2 is a signal flow diagram illustrating a conventional write operation.

Referring to FIG. 2, the data input / output buffer 100 inputs data Din in synchronization with rising and falling edges of pulse signals uds_f, uds_r, lds_f, and lds_r output from the data strobe buffer. 140 receives a write command (Write CMD) and the cas signal generator 150 receives the control buffer 140 receives a write command (Write CMD) and the cas signal generator 150 of the control buffer 140 A light column signal casp6_wt is output by synchronizing an output with the clock signal clkp4, and the light column signal casp6_wt controls the column line selection signal yi. yi is controlled in response to the clock signal clkp4.

Since the burst length is 4, four data D0, D1, D2, and D3 are continuously input. The upper data input / output signal UDQ receives the first data from 3/4 clock cycles tCLK to 5/4 clock cycles tCLK of the clock CLK, and the lower data input / output signal LDQ receives the upper data input / output. When the first data of the signal UDQ is input, the first data is received after a clock cycle tCLK of 1/2. The third data D2 of the upper data input / output signal UDQ is generated by the second pulse of the pulse signal uds_r outputted from the upper data strobe buffer and activated at the rising edge of the upper data strobe signal UDS. The second data of the lower data input / output signal LDQ by the first pulse of the pulse signal lds_f which is input through 100 and is output from the lower data strobe buffer and is activated at the falling edge of the lower data strobe signal LDS. D1) is input through the data input buffer (100 in FIG. 1). Since the write latency is 2, data can be transmitted to the cell block 170 after two clock cycles (CLK) from the start of the write command, and the upper data input / output signal is used because the 2-bit prefetch method is used. The time at which the data D2 input from the UDQ and the data D1 input from the lower data input / output signal LDQ can be simultaneously transmitted is T2 as shown in FIG.

When the write command is input at T0 indicating the time at which the write command shown in FIG. 2 is input during the write operation, the clock CLK at the time T2 at which the internal light starts through the write latency shown in FIG. The internal column signal casp6_wt is enabled by the clock signal clkp4 generated at the rising edge of the column line selection signal Yi. The clock signal clkp4, which is synchronized at T2 indicating the start point of the internal write shown in FIG. 2, is generated from the lower data strobe buffer and generated at the falling edge of the lower data strobe signal LDS. A quarter clock cycle tCLK is later.

Therefore, in the conventional write method described above, the pulse signal uds_r generated at the rising edge of the upper data strobe signal UDS and the falling pulse of the lower data strobe signal LDS are generated by the pulse signal lds_f. Since the data Din is received from the data input buffer 100, a problem occurs that the time at which the internal column signal casp6_wt is activated is 1/4 clock cycles later than the time at which the data Din is input. .

The present invention has been made to solve the above-described problems of the prior art, the light control device for implementing a write access time (Quick Access Time) as fast as 1/4 clock cycle (tCLK) than the conventional method in the write operation It is an object of the present invention to provide a dial-synchronous memory having a.

1 is a block diagram showing a conventional light path;

2 is a signal flow diagram showing a conventional write operation;

3 is a block diagram showing a column path and a data path to which the light control device of the present invention is applied;

4 is a signal flowchart showing an enable path of the column line selection signal Yi to which the light control device of the present invention is applied;

5 is a detailed circuit diagram of the light control device of the present invention;

6 is a signal flow diagram of a light control device of the present invention;

* Explanation of symbols for the main parts of the drawings

510: first input terminal 520: second input terminal

530: latch stage 540: output stage

In order to achieve the above object, the dial-synchronized memory device of the present invention is a semiconductor memory device, comprising: means for inputting a pulse signal generated at a falling edge of an upper data strobe signal and a pulse signal generated at a falling edge of a lower data strobe signal; Means for inputting and a light column control unit for detecting a later input of the two pulse signals and outputting a column signal.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the technical idea of the present invention. do.

3 is a block diagram showing a data input path and a column path to which the present invention is applied.

Referring to FIG. 3, a data input buffer receiving input data Din and buffering a data signal in synchronization with rising and falling edges of pulse signals uds_f, uds_r, lds_f, and lds_r output from the data strobe buffer ( 100) and the data strobe in synchronization with the pulse signal (uds_f, lds_f) generated by the falling edge of the data strobe signal among the pulse signals output from the data strobe buffer by receiving the data signal output from the data input buffer 100 A delay locked loop receiving a first data input unit 110 for aligning a data signal output from the data input buffer 100 and an output signal of the first data input unit 110 on a falling edge of the signal; The second data input unit 120 and the second data input unit 120 that align the signal output from the first data input unit 100 to the clock signal din_data output from the output of the second data input unit 120. The data input path circuit unit 130 receives the signal and transmits the signal input to the cell block 170. The pulse signal uds_f and the lower data strobe signal generated at the falling edge of the upper data strobe signal UDS are provided. A light column control unit 300 for detecting a later input among the pulse signals lds_f generated at the falling edge of the LDS and outputting the light column signal casp6_wt, and a light column that is an output of the light column control unit 300. A column path circuit unit 160 which receives the signal casp6_wt and transmits a column line selection signal yi to the cell block 170, a write data signal din from the data input path circuit unit 130 and the column; The cell block 170 receives the column line selection signal yi from the path circuit unit 160 and stores the data.

4 is a signal flow diagram of a light path to which the present invention is applied.

Referring to FIG. 4, the write column signal casp6_wt is enabled by the pulse signal lds_f generated at the falling edge of the lower data strobe signal LDS of the lower data strobe signal LDS, and the write column is enabled. The column line selection signal yi is enabled by the signal casp6_wt. Since the time point at which the signal lds_f generated at the falling edge of the lower data strobe signal LDS is activated is 1/4 clock cycle tCLK ahead of T2 which indicates the time point after the write latency, The column select signal Yi can be quickly activated.

5 is a detailed circuit diagram illustrating the light column controller 300 of the present invention.

Referring to FIG. 5, when the write command is input, the write column controller 300 receives the upper data strobe falling signal generated at the falling edge of the write control signal en_dinb and the upper data strobe signal UDS, which are activated as logic lows. (uds_f) and the first input terminal 310 for generating the first output signal dis_ldsb in response to the second output signal dis_udsb output from the second input terminal 320 to be described later; The low data strobe falling signal lds_f generated at the falling edge of the write control signal en_dinb and the lower data strobe signal LDS activated low and the first output signal dis_1dsb output from the first input terminal 310. A second input terminal 320 for generating a second output signal dis_udsb in response to the latch, a latch stage 330 for latching the first output signal dis_ldsb and a second output signal dis_udsb, and a first output Signal (dis_ldsb) The first inverting means INV1 for inverting the phase, the second inverting means INV3 for inverting the phase of the second output signal dis_udsb, and the signal udsf_selb outputted from the first inverting means INV1. ) And the upper data strobe falling signal uds_f in response to the signal ldsf_selb and the upper data strobe falling signal uds_f and the lower data strobe falling signal lds_f outputted from the second inverting means INV3. An output terminal 340 for outputting a final output signal last_dsf by selecting a signal input later from the lower data strobe falling signal lds_f.

The first input terminal 310 receives an inverter INVO for inverting the write control signal en_dinb, an output of the inverter INVO as a gate terminal, and a drain terminal of which is a power source voltage and a source terminal of the first input terminal. A first PMOS transistor (PO) connected to an output node of 310, a series connected to an output node and a ground terminal of the first input terminal 310, and each gate terminal is connected to an upper data strobe falling signal (uds_f) Three NMOS transistors NO, N1 and N2 connected to the output signal dis_udsb of the second input terminal 320 and the output signal of the inverter INVO, and the gate terminal of the second input terminal 320 are output. The second PMOS transistor P1 is connected to the signal disudsb and has a source-drain path having a power supply voltage and an output signal dis_ldsb of the first input terminal 310.

The second input terminal 320 receives an inverter INV2 for inverting the write control signal en_dinb and an output of the inverter INV2 as a gate terminal, and a drain terminal is a power supply voltage and a source terminal is the second input terminal. A first PMOS transistor P2 connected to an output signal of dis_udsb, an output signal of dis_udsb of the second input terminal and a ground connected in series, and each gate terminal thereof is connected to the lower data strobe falling signal lds_f Three NMOS transistors N3, N4 and N5 connected to an output signal dis_ldsb of the first input terminal 370 and an output signal of the inverter INV2, and a gate terminal of the first input terminal 310. A second PMOS transistor P3 is connected to the signal dis_ldsb and has a source-drain path formed at a power supply voltage and an output signal dis_udsb of the second input terminal.

The latch stage 330 includes first and second PMOS transistors P4 and P5 having drains connected to a power supply voltage and respective gate-source terminals cross-coupled.

The output terminal 340 may include a first NOR gate NORO and an output from the second inverting means INV3 that negate and logically output the first inverting means INV1 and the upper data strobe falling signal uds_f. A second output signal last_dsf is formed by performing a negative logic operation on the second NOR gate NOR1, which negatively combines the lower data scrub falling signal lds_f, and the first Noah gate NORO, and the second Noah gate NOR1. And a third NOR gate NOR2 for outputting the same.

With reference to the signal flow diagram of Figure 6 looks at with respect to the operation of the present invention having the above configuration.

5 and 6, first, when the write control signal en_dinb is in a logic state, the first PMOS transistor P0 of the first input terminal is turned on to output the output signal of the first input terminal. After the precharge of dis_ldsb and the write control signal en_dinb is activated from logic high to logic low, the upper data strobe falling signal uds_f is input before the lower data strobe falling signal lds_f. When the upper data strobe falling signal uds_f is first activated to a logic high and the output signal dis_udsb of the second input terminal maintains a previous logic high state, the NMOS transistors N0 and N1 of the first input terminal. N2 is turned on so that the output signal dis_ldsb of the first input terminal is changed to a logic low state. When the output signal dis_ldsb of the first input terminal is changed to a logic low state, the first PMOS transistor P5 of the latch stage 330 is turned on and the second PMOS of the latch stage 330 is turned on. Even when the transistor N4 is turned off and the lower data strobe falling signal lds_f is activated, the output signal dis_udsb of the second input terminal remains in a logic high state, and the output signal dis_ldsb of the first input terminal is turned off. Keeps a logic low state. When the output signal dis_lasb of the first input terminal 310 is activated from logic high to logic low, a signal udsf_selb inverted by the first inverting means INV1 and rising from logic low to logic high is generated. A signal is input to the first NOR gate NORO of the output terminal 340 to maintain the logic low state of the input signal net0 of the third NOR gate NOR2. Since the output signal dis_udsb of the second input terminal is logic high, it is inverted by the second inverting means INV3 to make one input of the second NOR gate NOR1 of the output terminal 340 to be logic low, and also the second When the lower data strobe falling signal lds_f used as another input signal of the NOR gate NOR1 inputs a logic high pulse, the output signal net1 of the second NOR gate NOR1 is inverted to generate a signal. As a result, the final output signal last_dsf is output through the third NOR gate NOR2.

The write control signal en_dinb is disabled to a logic high level after the write data input is completed, so that the write column control unit 300 does not operate. If the upper and lower data strobe falling signals uds_f and lds_f are activated after the write control signal en_dinb is disabled due to a malfunction, the output of the first NOR gate NORO of the output terminal 340 is activated. Since there is no section in which the signal net0 and the output signal net1 of the second NOR gate NOR1 are logic low at the same time, the final output signal last_dsf does not output an invalid high pulse.

Although the technical idea of the present invention has been described in detail according to the above preferred embodiment, it should be noted that the above-described embodiment is for the purpose of description and not of limitation. In addition, those skilled in the art will understand that various embodiments are possible within the scope of the technical idea of the present invention.

The present invention as described above can improve the write access time and the write recovery time by increasing the write operation speed, and eliminates unnecessary circuits used in the write operation. It is advantageous to secure a layout area.

Claims (6)

In a semiconductor memory device, A data input buffer configured to receive input data and buffer the data signal in synchronization with rising and falling edges of the pulse signals output from the data strobe buffer; A first data input unit which receives the data signal output from the data input buffer means and aligns the data signal output from the data input buffer means on the falling edge of the data strobe signal; Means for inputting a pulse signal generated at the falling edge of the upper data strobe signal, means for inputting a pulse signal generated at the falling edge of the lower data strobe signal, and detecting a later input among the two pulse signals to generate a light column signal. A light column controller for outputting; And A column path circuit unit receiving a light column signal output from the light column controller and transferring a column line selection signal to a cell block Dial synchronizing memory device comprising a. The method of claim 1, The light column control unit, When the write command is input, the first output signal is responsive to the write control signal activated to the logic low, the upper data strobe falling signal generated at the falling edge of the upper data strobe signal, and the second output signal output from the following second input terminal. A first input for generating a; When the write command is input, a second output signal is generated in response to a write control signal activated to a logic low, a lower data strobe falling signal generated at the falling edge of the lower data strobe signal, and a first output signal output from the first input terminal. Generating the second input terminal; A latch stage for latching the first output signal and the second output signal; First inverting means for inverting a phase of the first output signal; Second inverting means for inverting the phase of the second output signal; And The upper data strobe falling signal and the lower data strobe falling signal in response to the signal output from the first inverting means, the signal output from the second inverting means, the upper data strobe falling signal and the lower data strobe falling signal signal. Output terminal which selects the late input signal and outputs the final output signal Dial synchronous memory device comprising a. The method of claim 2, The first input terminal, A first inverter for inverting the light control signal; A first PMOS transistor configured to receive an output of the first inverter through a gate terminal, and a source-drain path formed between a power supply voltage terminal and an output node of the first input terminal; Three NMOSs connected in series between the output node of the first input terminal and the ground terminal, and each gate terminal receives the upper data strobe falling signal, the output signal of the second input terminal, and the output signal of the first inverter. transistor; And A second PMOS transistor having a gate terminal connected to an output signal of the second input terminal and a source-drain path formed between a power supply voltage terminal and an output terminal of the first input terminal; Dial synchronous memory device comprising a The method of claim 2, The second input terminal, A first inverter for inverting the light control signal; A first PMOS transistor having an output of the first inverter input to a gate terminal, a drain terminal connected to a power supply voltage, and a source terminal connected to an output node of the second input terminal; Three NMOS transistors connected in series with the output signal of the first input terminal and the ground and each gate terminal receives the lower data strobe falling signal, the output signal of the first input terminal, and the output signal of the first inverter; A second PMOS transistor whose gate end receives the output signal of the first input end and whose source-drain path is the power supply voltage and the output node of the second input end Dial synchronizing memory device comprising a. The method of claim 2, The latch stage, First and second PMOS transistors having a drain connected to the supply voltage and respective gate-source stages cross-coupled Dial synchronizing memory device comprising a. The method of claim 2, The output stage, A first NOR gate for negating and logically outputting the first data strobe falling signal from the first inverting means; A second NOR gate that negates and logically outputs the second data scrub down signal from the second inverting means; A third noah gate that selects one of the upper data strobe falling signal and the lower data scrub falling signal later and negatively combines the first and second noah gates to output a final output signal Dial synchronizing memory device comprising a.