Abstract: An apparatus for allowing a RAM array within an SRAM to be tested via scan ATPG is disclosed. A first clocked flip-flop has a data input latched high, a scan-in input latched high, a clock input coupled to a signal source generating a periodic waveform, a scan-enable input coupled to a scan enable signal, and an output. The first flip-flop inverts the data input at the output when the scan enable signal is low, and places the scan-in input signal at the output when the scan enable signal is high. A second clocked flip-flop has a data input coupled to the output of the first flip-flop, a scan-in input latched high, a clock input coupled to the signal source, a scan enable input coupled to the scan enable signal, and an output. The second flip-flop inverts the data input at the output when the scan enable signal is low, and places the scan-in input signal at the output when the scan enable signal is high.

Abstract: An apparatus for allowing a RAM array within an SRAM to be tested via scan ATPG is disclosed. A first clocked flip-flop has a data input latched high, a scan-in input latched high, a clock input coupled to a signal source generating a periodic waveform, a scan-enable input coupled to a scan enable signal, and an output. The first flip-flop inverts the data input at the output when the scan enable signal is low, and places the scan-in input signal at the output when the scan enable signal is high. A second clocked flip-flop has a data input coupled to the output of the first flip-flop, a scan-in input latched high, a clock input coupled to the signal source, a scan enable input coupled to the scan enable signal, and an output. The second flip-flop inverts the data input at the output when the scan enable signal is low, and places the scan-in input signal at the output when the scan enable signal is high.

Abstract: A method for allowing a RAM array within an SRAM to be tested via scan ATPG is disclosed. A first clocked flip-flop has a data input latched high, a scan-in input latched high, a clock input coupled to a signal source generating a periodic waveform, a scan-enable input coupled to a scan enable signal, and an output. The first flip-flop inverts the data input at the output when the scan enable signal is low, and places the scan-in input signal at the output when the scan enable signal is high. A second clocked flip-flop has a data input coupled to the output of the first flip-flop, a scan-in input latched high, a clock input coupled to the signal source, a scan enable input coupled to the scan enable signal, and an output. The second flip-flop inverts the data input at the output when the scan enable signal is low, and places the scan-in input signal at the output when the scan enable signal is high.

Abstract: An apparatus for allowing a RAM array within an SRAM to be tested via scan ATPG is disclosed. A first clocked flip-flop has a data input latched high, a scan-in input latched high, a clock input coupled to a signal source generating a periodic waveform, a scan-enable input coupled to a scan enable signal, and an output. The first flip-flop inverts the data input at the output when the scan enable signal is low, and places the scan-in input signal at the output when the scan enable signal is high. A second clocked flip-flop has a data input coupled to the output of the first flip-flop, a scan-in input latched high, a clock input coupled to the signal source, a scan enable input coupled to the scan enable signal, and an output. The second flip-flop inverts the data input at the output when the scan enable signal is low, and places the scan-in input signal at the output when the scan enable signal is high.