A deterioration detection device includes a storage including a first current path and a second current path and configured such that a current is applied to the first current path and the second current path, a storage input control unit configured to compare an internal operating condition of a memory device with a target condition in a first operating mode and to select one of the first current path and the second current path of the storage based on a result of the comparison, and an output unit configured to output an output signal indicated deterioration, accumulated in one of the first current path and the second current path, in a second operating mode.

A semiconductor structure is provided. The semiconductor structure includes a transistor and a memory device. The transistor includes a source, a drain, and a gate. The memory device is disposed at a drain side of the transistor and coupled to the drain. The memory device includes a first electrode, a switch layer, a memory layer, and a second electrode disposed sequentially. The first electrode is coupled to the drain.

A process is provided to trim PCRAM cells to have consistent programming curves. Initial programming curves of PCRAM cells are measured. A target programming curve is set up for the PCRAM cells. Each PCRAM cell is then modulated individually to meet the target programming curve.

A semiconductor device includes memory cells, word lines, a row address decoder, word line drivers, a first switch transistor, and second switch transistors. The switch transistor is provided between the word line drivers and a power supply potential terminal. Each second switch transistor is provided between each word line and a reference potential terminal. The row address decoder activates all of decode signals corresponding to the memory cells to which a burn-in test is performed collectively. The first switch transistor has a lower driving capability than a total driving capability of two P-channel MOS transistors included in inverters of two word line drivers. Each second switch transistor has a lower driving capability than a driving capability of an N-channel MOS transistor included in the inverter of each word line driver.

Methods, systems, and devices for performing quick precharge command sequences are described. An operating mode that is associated with a command sequence having a reduced duration relative to another operating mode may be configured at a memory device. The operating mode may be configured based on determining that a procedure does not attempt to preserve or is independent of preserving a logic state of accessed memory cells, among other conditions. While operating in the mode, the memory device may perform a received precharge command using a first set of operations having a first duration—rather than a second set of operations having a second set of operations having a second, longer duration—to perform the received precharge command. The first set of operations may also use less current or introduce less disturbance into the memory device relative to the second set of operations.

An electronic device includes a masking signal generation circuit configured to generate a test masking signal by receiving a fuse data during a period in which a test masking mode is executed; and a test mode signal generation circuit configured to, when a test command for executing a test in an internal circuit is input, execute the test based on the test masking signal.

A burn-in board for testing the operational integrity of memory devices includes local heating elements for each memory device under test. Each socket on the burn-in board may include a pair of opposed latch heads which move between open positions allowing a memory device to be mounted in the socket, and closed positions where the latch heads rest against the memory device to secure the device in the socket. Local heating elements may be integrated into the latch heads to ensure even heating of each memory device in the burn-in board.

A thermal chamber includes a cavity that is enclosed by sides and one or more ports that expose the cavity within the thermal chamber. Each of the one or more ports is configured to receive a temperature control component having a solid physical structure and configured to transfer thermal energy to and from an electrical device exposed via the cavity. The thermal chamber includes a bottom side open area of the thermal chamber located below the one or more ports. The bottom side open area is configured to allow the temperature control component to contact the electrical device that is exposed via the bottom side open area.

Provided is a booster circuit enabling improvement of efficiency of a stress test for a circuit to which a boosted voltage is applied. A voltage divider circuit is configured to have a voltage-dividing ratio that is variable depending on a test signal, and a limiter circuit is configured to clamp a voltage to a voltage higher than a boosted voltage in normal operation. In a test mode, the voltage divider circuit is controlled so that the boosted voltage becomes higher than that in the normal operation, and the limiter circuit clamps the boosted voltage, with the result that a booster section continuously operates.

A process is provided to trim PCRAM cells to have consistent programming curves. Initial programming curves of PCRAM cells are measured. A target programming curve is set up for the PCRAM cells. Each PCRAM cell is then modulated individually to meet the target programming curve.