A method is provided in which a monitor cell is made that is substantially identical to the flash memory cells of an embedded memory array. The monitor cell is formed simultaneously with the cells of the memory array, and so in certain critical aspects, is exactly comparable. An aperture is formed that extends through the control gate and intervening dielectric to the floating gate of the monitor cell. To prevent silicide contamination during a subsequent CMP process, a silicide protection layer (SPL), such as a resist protective oxide, is formed over exposed portions of the control gate prior to formation of a silicide contact formed on the floating gate. The SPL is formed simultaneously with existing manufacturing processes to avoid additional process steps.

In a memory component having a page buffer with 2.sup.N independently accessible regions, N bits of a command/address value are decoded to access contents within a first one of the 2.sup.N page-buffer regions if a configuration value specifies a first addressing resolution and, if the configuration value specifies a second addressing resolution, a composite address that includes fewer than N bits of the command/address value together with a plurality of bits generated within the memory component to access contents within a second one of the 2.sup.N page-buffer regions.

In a memory component having a page buffer with 2.sup.N independently accessible regions, N bits of a command/address value are decoded to access contents within a first one of the 2.sup.N page-buffer regions if a configuration value specifies a first addressing resolution and, if the configuration value specifies a second addressing resolution, a composite address that includes fewer than N bits of the command/address value together with a plurality of bits generated within the memory component to access contents within a second one of the 2.sup.N page-buffer regions.

A chip detection method includes: providing a chip to be tested, the chip having multiple one-time programmable memories (OTPMs); transmitting a test signal to the chip to maintain the OTPMs in the chip in a latched state; and detecting whether the chip emits a low-light signal, and if yes, determining that an OTPM is leaky. The chip detection method and device can detect an OTPM that is burnt through by mistake, and can also detect an OTPM that has slight leakage, thereby preventing a defective product with a potential burn-through risk from entering a subsequent production process.

A chip detection method includes: providing a chip to be tested, the chip having multiple one-time programmable memories (OTPMs); transmitting a test signal to the chip to maintain the OTPMs in the chip in a latched state; and detecting whether the chip emits a low-light signal, and if yes, determining that an OTPM is leaky. The chip detection method and device can detect an OTPM that is burnt through by mistake, and can also detect an OTPM that has slight leakage, thereby preventing a defective product with a potential burn-through risk from entering a subsequent production process.

A test rack includes two or more memory device test boards where each memory device test boards includes two or more memory device test resources. Each of the two or more memory device test boards includes a separate processing device allocated to the memory device test resources of a corresponding memory device test boards. A processing device of a test board detects that a first memory sub-system has engaged with a first memory device test resource of the corresponding memory device test board. The processing device identifies a first test to be performed for a first memory device of the first memory sub-system, where the first test includes one or more first test instructions to be executed in performance of the first test. The processing device causes the one or more first test instructions to be transmitted to the first memory sub-system, where the first test is performed by the one or more first test instructions executing at the first memory sub-system.

A test rack includes two or more memory device test boards where each memory device test boards includes two or more memory device test resources. Each of the two or more memory device test boards includes a separate processing device allocated to the memory device test resources of a corresponding memory device test boards. A processing device of a test board detects that a first memory sub-system has engaged with a first memory device test resource of the corresponding memory device test board. The processing device identifies a first test to be performed for a first memory device of the first memory sub-system, where the first test includes one or more first test instructions to be executed in performance of the first test. The processing device causes the one or more first test instructions to be transmitted to the first memory sub-system, where the first test is performed by the one or more first test instructions executing at the first memory sub-system.

A detection is made by a processing device allocated to a memory device test board of a distributed test platform that a memory sub-system has engaged with a memory device test resource of the memory device test board. A test is identified to be performed for a memory device of the memory sub-system. The test includes first instructions to be executed by a memory sub-system controller of the memory sub-system in performance of the test and second instructions to be executed by the processing device in performance of the test. The second instructions are to cause one or more test condition components of the memory device test resource to generate one or more test conditions to be applied to the memory device while the memory sub-system executes the first instructions. Responsive to a transmission of the first instructions to the memory sub-system controller, the second instructions are executed.

A detection is made by a processing device allocated to a memory device test board of a distributed test platform that a memory sub-system has engaged with a memory device test resource of the memory device test board. A test is identified to be performed for a memory device of the memory sub-system. The test includes first instructions to be executed by a memory sub-system controller of the memory sub-system in performance of the test and second instructions to be executed by the processing device in performance of the test. The second instructions are to cause one or more test condition components of the memory device test resource to generate one or more test conditions to be applied to the memory device while the memory sub-system executes the first instructions. Responsive to a transmission of the first instructions to the memory sub-system controller, the second instructions are executed.

A test rack includes two or more memory device test boards where each memory device test boards includes two or more memory device test resources. Each of the two or more memory device test boards includes a separate processing device allocated to the memory device test resources of a corresponding memory device test boards. A processing device of a test board detects that a first memory sub-system has engaged with a first memory device test resource of the corresponding memory device test board. The processing device identifies a first test to be performed for a first memory device of the first memory sub-system, where the first test includes one or more first test instructions to be executed in performance of the first test. The processing device causes the one or more first test instructions to be transmitted to the first memory sub-system, where the first test is performed by the one or more first test instructions executing at the first memory sub-system.