Abstract: Embodiments of design-for-test (DFT) apparatuses and related techniques are disclosed herein. In some embodiments, a DFT apparatus may include an SRAM cell, read/write (R/W) circuitry to provide a nominal word line (WL) voltage and a nominal BL voltage for application to the SRAM cell during accesses. The DFT apparatus may also include test circuitry having an activated state and a deactivated state. When the test circuitry is in the activated state, in some embodiments, the WL voltage and/or the BL voltage applied to the SRAM cell may be different from the nominal voltages provided by the R/W/decoder circuitry. The R/W/decoder circuitry may be operated to perform accesses to the SRAM cell while the test circuitry is in the activated state. Other embodiments may be disclosed and/or claimed.

Abstract: Assist circuits for SRAM memory tests allow voltage scaling in low-power SRAMs. Word line level reduction (WLR) and negative bit line (NBL) boost assist techniques improve read stability and write margin of SRAM core-cells, respectively, when the memory operates at a lowered supply voltage. Assist circuits are activated at particular points in the memory cell circuit. The assist circuits are selectively activated for modifying the voltage along particular circuit elements to identify the potential defects that might be otherwise masked until substantially large. A March test invokes elements for activating the assist circuits to identify defects and indicate functional fault models (FFMs) associated with the defects.

Abstract: Embodiments of design-for-test (DFT) apparatuses and related techniques are disclosed herein. In some embodiments, a DFT apparatus may include an SRAM cell, read/write (R/W) circuitry to provide a nominal word line (WL) voltage and a nominal BL voltage for application to the SRAM cell during accesses. The DFT apparatus may also include test circuitry having an activated state and a deactivated state. When the test circuitry is in the activated state, in some embodiments, the WL voltage and/or the BL voltage applied to the SRAM cell may be different from the nominal voltages provided by the R/W/decoder circuitry. The R/W/decoder circuitry may be operated to perform accesses to the SRAM cell while the test circuitry is in the activated state. Other embodiments may be disclosed and/or claimed.

Abstract: Embodiments of design-for-test (DFT) apparatuses and related techniques are disclosed herein. In some embodiments, a DFT apparatus may include a static random access memory (SRAM) cell, read/write/decoder (R/W/decoder) circuitry to provide a nominal word line (WL) voltage and a nominal bit line (BL) voltage for application to the SRAM cell during accesses. The DFT apparatus may also include test circuitry having an activated state and a deactivated state. When the test circuitry is in the activated state, in some embodiments, the WL voltage and/or the BL voltage applied to the SRAM cell may be different from the nominal voltages provided by the R/W/decoder circuitry. The R/W/decoder circuitry may be operated to perform accesses to the SRAM cell while the test circuitry is in the activated state. Other embodiments may be disclosed and/or claimed.

Abstract: Assist circuits for SRAM memory tests allow voltage scaling in low-power SRAMs. Word line level reduction (WLR) and negative bit line (NBL) boost assist techniques improve read stability and write margin of SRAM core-cells, respectively, when the memory operates at a lowered supply voltage. Assist circuits are activated at particular points in the memory cell circuit. The assist circuits are selectively activated for modifying the voltage along particular circuit elements to identify the potential defects that might be otherwise masked until substantially large. A March test invokes elements for activating the assist circuits to identify defects and indicate functional fault models (FFMs) associated with the defects.

Abstract: A circuit arrangement may include: a memory, composed of a memory cell array, including a plurality of memory cells, and a peripheral circuitry; a voltage source configured to provide at least one supply voltage; a test circuit integrated with the memory cell array and the voltage source, wherein the test circuit receives the supply voltage; the test circuit including: at least one test memory cell; at least one failure detection circuit configured to detect a data retention failure in the at least one test memory cell.

Abstract: Embodiments of design-for-test (DFT) apparatuses and related techniques are disclosed herein. In some embodiments, a DFT apparatus may include a static random access memory (SRAM) cell, read/write/decoder (R/W/decoder) circuitry to provide a nominal word line (WL) voltage and a nominal bit line (BL) voltage for application to the SRAM cell during accesses. The DFT apparatus may also include test circuitry having an activated state and a deactivated state. When the test circuitry is in the activated state, in some embodiments, the WL voltage and/or the BL voltage applied to the SRAM cell may be different from the nominal voltages provided by the R/W/decoder circuitry. The R/W/decoder circuitry may be operated to perform accesses to the SRAM cell while the test circuitry is in the activated state. Other embodiments may be disclosed and/or claimed.

Abstract: A circuit arrangement may include: a memory, composed of a memory cell array, including a plurality of memory cells, and a peripheral circuitry; a voltage source configured to provide at least one supply voltage; a test circuit integrated with the memory cell array and the voltage source, wherein the test circuit receives the supply voltage; the test circuit including: at least one test memory cell; at least one failure detection circuit configured to detect a data retention failure in the at least one test memory cell.