Abstract: A multi-port memory device includes ports, banks, a global data bus, an input/output (I/O) controller, mode register set (MRS), a clock generator, and a test I/O controller. The I/O controller transmits a test signal to the global data bus in response to a mode register enable signal. The MRS generates a test enable signal in response to the mode register enable signal and outputs a mode selection signal which determines a data transmission mode of a test I/O signal in response to the test signal. The clock generator receives an external clock and generates an internal clock based on the external clock in response to the mode selection signal. The test I/O controller inputs/outputs the test I/O signal in synchronism with the internal clock. The mode register enable signal active during a test operation mode for testing a core area of the banks.

Abstract: A delay locked loop circuit includes a delay locking unit configured to output a first internal clock and a second internal clock, a rising edge of which is synchronized with that of the first internal clock by delaying a compensated external clock for compensating a skew of a semiconductor memory device; a duty ratio compensation unit configured to generate the compensated external clock by compensating a duty ratio of an external clock of the semiconductor memory device and to compensate duty ratios of the first and second internal clocks; and a clock control unit configured to control an activation state of the second internal clock after the duty ratio compensation of the external clock.

Abstract: A multi-port memory device includes a plurality of ports, a plurality of bank control units, a plurality of banks, a read clock generation unit, and a data transmission unit. Each of the banks is connected to a corresponding one of the bank control units. The read clock generation unit generates a read clock toggling for four clocks in response to a read command. The data transmission unit transmits a read data from the banks to a corresponding one of the ports in response to the read clock. Every bank control unit is connected to all of the ports.

Abstract: Provided is a semiconductor memory device and a driving method for initializing an internal logic circuit within the semiconductor memory device under a stable state of a source voltage without an extra reset pin. The semiconductor memory device includes a power-up signal generating unit for generating a power-up signal; an internal reset signal generating unit for generating an internal reset signal in response to a pad signal inputted from an arbitrary external pin during a test mode; an internal logic initializing signal generating unit for generating an internal logic initializing signal based on the power-up signal and the internal reset signal; and an internal logic unit initialized in response to the internal logic initializing signal.

Abstract: In a multi-port memory device, a plurality of ports simultaneously access a plurality of banks through global data buses. A data conflict detector compares valid data signals input from the plurality of ports through the global data buses to the plurality of banks, and detects data conflict caused when the valid data signals are simultaneously input to the same bank.

Abstract: Provided is a semiconductor memory device and a driving method for initializing an internal logic circuit within the semiconductor memory device under a stable state of a source voltage without an extra reset pin. The semiconductor memory device includes a power-up signal generating unit for generating a power-up signal; an internal reset signal generating unit for generating an internal reset signal in response to a pad signal inputted from an arbitrary external pin during a test mode; an internal logic initializing signal generating unit for generating an internal logic initializing signal based on the power-up signal and the internal reset signal; and an internal logic unit initialized in response to the internal logic initializing signal.

Abstract: Semiconductor memory device includes a cell array including a plurality of unit cells; and a test circuit configured to perform a built-in self-stress (BISS) test for detecting a defect by performing a plurality of internal operations including a write operation through an access to the unit cells using a plurality of patterns during a test procedure carried out at a wafer-level.

Abstract: A semiconductor memory device adjusts an activation timing and pulse width of a pin strobe signal according to a power supply voltage variation, and thereby loads data on a pipelatch properly and prevents an activation period of a pin strobe signal from falling out of a period for valid data. The semiconductor memory device includes a voltage detector configured to detect a level of a power supply voltage to output a detection signal, a pin strobe signal transfer path configured to transfer a pin strobe signal determining an input timing of data to a pipelatch, a delay controller configured to control a delay value of the pin strobe signal transfer path in response to the detection signal, and a pulse width modulator configured to modulate a pulse width of the pin strobe signal in response to the detection signal.

Abstract: A fuse apparatus for controlling a built-in self stress unit including a built-in self stress configured to repeatedly generate any stress test pattern in a test mode, and generate a one-cycle end signal when one cycle for the generated stress test pattern has ended, and a fuse configured to record a operation state of the built-in self stress according to the one-cycle end signal.

Abstract: A multi-port memory device includes a plurality of ports, a plurality of bank control units, a plurality of banks, a read clock generation unit, and a data transmission unit. Each of the banks is connected to a corresponding one of the bank control units. The read clock generation unit generates a read clock toggling for four clocks in response to a read command. The data transmission unit transmits a read data from the banks to a corresponding one of the ports in response to the read clock. Every bank control unit is connected to all of the ports.

Abstract: A multi-port memory device includes ports, banks, a global data bus, an input/output (I/O) controller, mode register set (MRS), a clock generator, and a test I/O controller. The I/O controller transmits a test signal to the global data bus in response to a mode register enable signal. The MRS generates a test enable signal in response to the mode register enable signal and outputs a mode selection signal which determines a data transmission mode of a test I/O signal in response to the test signal. The clock generator receives an external clock and generates an internal clock based on the external clock in response to the mode selection signal. The test I/O controller inputs/outputs the test I/O signal in synchronism with the internal clock. The mode register enable signal active during a test operation mode for testing a core area of the banks.

Abstract: A multi-port memory device includes a plurality ports, a plurality of banks, a plurality of global data buses, first and second I/O controllers, and a test input/output (I/O) controller. The ports perform a serial I/O data transmission. The banks perform a parallel I/O data transmission with the ports. The global data buses are employed for transmitting data between the ports and the banks. The first I/O controller controls a serial data transmission between the ports and external devices. The second I/O controller controls a parallel data transmission between the ports and the global buses. The test I/O controller generates test commands based on a test command/address (C/A) inputted from the external devices and transmits a test I/O data with the global data bus during a test operation mode.

Abstract: In a multi-port memory device, a plurality of ports simultaneously access a plurality of banks through global data buses. A data conflict detector compares valid data signals input from the plurality of ports through the global data buses to the plurality of banks, and detects data conflict caused when the valid data signals are simultaneously input to the same bank.

Abstract: Provided is a semiconductor memory device and a driving method for initializing an internal logic circuit within the semiconductor memory device under a stable state of a source voltage without an extra reset pin. The semiconductor memory device includes a power-up signal generating unit for generating a power-up signal; an internal reset signal generating unit for generating an internal reset signal in response to a pad signal inputted from an arbitrary external pin during a test mode; an internal logic initializing signal generating unit for generating an internal logic initializing signal based on the power-up signal and the internal reset signal; and an internal logic unit initialized in response to the internal logic initializing signal.