A semiconductor device includes a semiconductor die having a peripheral region surrounding, a defect detection circuit in the peripheral region, the defect detection circuit arranged in an open conduction loop, the defect detection circuit comprising a plurality of latch circuits and a plurality of defect detection conduction paths, each defect detection conduction path of the plurality of defect detection conduction paths connecting two adjacent latch circuits of the plurality of latch circuits, and a test control circuitry configured to perform (a) a test write operation by transferring bits of an input data pattern in a forward direction of the open conduction loop to cause the plurality of latch circuits to store the bits of the input data pattern in the plurality of latch circuits, and (b) a test read operation by transferring bits stored in the plurality of latch circuits in a backward direction of the open conduction loop.

A semiconductor device includes a plurality of first micro-bumps suitable for transferring normal signals; a plurality of a second micro-bumps suitable for transferring test signals; and a test circuit including a plurality of scan cells respectively corresponding to the first and second micro-bumps. The test circuit is suitable for applying signals stored in the respective scan cells to the first and second micro-bumps, feeding back the applied signals from the first and second micro-bumps to the respective scan cells, and sequentially outputting the signals stored in the scan cells to a test output pad.

A method of testing a semiconductor package including a plurality of semiconductor chips includes sensing electrical signals respectively output from a plurality of semiconductor chip groups each representing a combination of at least two semiconductor chips among the plurality of semiconductor chips, obtaining amplitudes of electrical signals respectively output from the plurality of semiconductor chips based on the plurality of sensed electrical signals, and outputting a test result for the semiconductor package by using the plurality of obtained electrical signals.

A semiconductor chip with error detection and correction includes multiple pipes and each pipe is coupled to one or more ports on the semiconductor chip. The semiconductor chip further includes a state machine coupled to the pipes to generate a number of events consisting of read- and/or scan-type events associated with a plurality of storage elements. The state machine is implemented in hardware and can centrally detect and correct erroneous memory entries across the plurality of storage elements.

A nonvolatile memory device includes a memory cell array, a voltage generator, a voltage path circuit and a wordline defect detection circuit. The memory cell array includes memory cells and wordlines connected to the memory cells. The voltage generator generates a wordline voltage applied to the wordlines. The voltage path circuit between the voltage generator and the memory cell array transfers the wordline voltage to the wordlines. The wordline defect detection circuit is connected to a measurement node between the voltage generator and the voltage path circuit. The wordline defect detection circuit measures a path leakage current of the voltage path circuit based on a measurement voltage of the measurement node to generate an offset value corresponding to the path leakage current in a compensation mode and determines defect of each wordline of the wordlines based on the offset value and the measurement voltage in a defect detection mode.

A flexible RAM loader including a shift register that includes a first data section coupled with a serial data input, and a second data section selectively coupled with a first parallel data input. The shift register is configured to load data serially from the serial data input to the first data section and the second data section when the second data section is uncoupled from the first parallel data input, and, when the second data section is coupled with the first parallel data input, configured to load data in parallel from the serial data input into the first data section and from the first parallel data input into the second data section. The flexible RAM loader also including a test register comprising a selection bit to couple the second data section with the first parallel data input.

Disclosed herein is an apparatus that includes a fuse array circuit including a plurality of fuse sets each assigned to a corresponding one of a plurality of fuse addresses and configured to operatively store a fuse data, and a first circuit configured to generate and sequentially update a fuse address to sequentially read the fuse data from the plurality of fuse sets. The first circuit is configured to change a frequency of updating the fuse address based on a first signal.

A method for testing a memory chip includes the following: test data is written into memory cells of a memory chip to be tested; stored data is read from memory cells; a test result of the memory chip to be tested is generated according to the test data and the stored data. A current voltage of bit line precharge (VBLP) of the memory chip to be tested is smaller than a standard VBLP of the memory chip to be tested, and/or a current sensing delay time (SDT) of the memory chip to be tested is smaller than a standard SDT of the memory chip to be tested.

A semiconductor chip is disclosed that includes a chip pad disposed in a first region of a chip body, a redistribution wiring test pad disposed in the first region of the chip body spaced apart from the chip pad and connected to the chip pad through a redistribution wiring structure, and a redistribution wiring connection pad disposed in the first region of the chip body or a second region of the chip body and connected to the chip pad through the redistribution wiring structure.

A latch circuit includes a latch module, a set control module, a reset control module and a clock module, wherein the latch module is employed for latching data input by a data module, the set control module is employed for controlling the latch module to output a high-level signal, the reset control module is employed for controlling the latch module to output a low-level signal, and the clock module is employed for providing a readout clock signal to the latch module.