Abstract: A memory device tester capable of testing for proper operation of reduced power states in memory devices. The memory device tester can include a processor or a state machine, each configured to send commands to the memory device, and to compare results. An example of a memory device that can be tested by the memory device tester is a Direct Rambus Dynamic Random Access Memory (DRDRAM). The described processing systems and other circuits can test a DRDRAM for proper operation in a standby (STBY) state. When the DRDRAM is in STBY, the column decoder is shut off to conserve power, and the DRDRAM should not respond to column packets on the column control bus. The method and apparatus provide for testing that the column decoder is shut off when in STBY with no banks active, which is the recommended usage pattern for the part.

Abstract: A memory device tester capable of testing for proper operation of reduced power states in memory devices. The memory device tester can include a processor or a state machine, each configured to send commands to the memory device, and to compare results. An example of a memory device that can be tested by the memory device tester is a Direct Rambus Dynamic Random Access Memory (DRDRAM). The described processing systems and other circuits can test a DRDRAM for proper operation in a standby (STBY) state. When the DRDRAM is in STBY, the column decoder is shut off to conserve power, and the DRDRAM should not respond to column packets on the column control bus. The method and apparatus provide for testing that the column decoder is shut off when in STBY with no banks active, which is the recommended usage pattern for the part.

Abstract: A memory device tester capable of testing for proper operation of reduced power states in memory devices. The memory device tester can include a processor or a state machine, each configured to send commands to the memory device, and to compare results. An example of a memory device that can be tested by the memory device tester is a Direct Rambus Dynamic Random Access Memory (DRDRAM). The described processing systems and other circuits can test a DRDRAM for proper operation in a standby (STBY) state. When the DRDRAM is in STBY, the column decoder is shut off to conserve power, and the DRDRAM should not respond to column packets on the column control bus. The method and apparatus provide for testing that the column decoder is shut off when in STBY with no banks active, which is the recommended usage pattern for the part.

Abstract: A memory device tester capable of testing for proper operation of reduced power states in memory devices. The memory device tester can include a processor or a state machine, each configured to send commands to the memory device, and to compare results. An example of a memory device that can be tested by the memory device tester is a Direct Rambus Dynamic Random Access Memory (DRDRAM). The described processing systems and other circuits can test a DRDRAM for proper operation in a standby (STBY) state. When the DRDRAM is in STBY, the column decoder is shut off to conserve power, and the DRDRAM should not respond to column packets on the column control bus. The method and apparatus provide for testing that the column decoder is shut off when in STBY with no banks active, which is the recommended usage pattern for the part.

Abstract: A memory device tester capable of testing for proper operation of reduced power states in memory devices. The memory device tester can include a processor or a state machine, each configured to send commands to the memory device, and to compare results. An example of a memory device that can be tested by the memory device tester is a Direct Rambus Dynamic Random Access Memory (DRDRAM). The described processing systems and other circuits can test a DRDRAM for proper operation in a standby (STBY) state. When the DRDRAM is in STBY, the column decoder is shut off to conserve power, and the DRDRAM should not respond to column packets on the column control bus. The method and apparatus provide for testing that the column decoder is shut off when in STBY with no banks active, which is the recommended usage pattern for the part.

Abstract: A memory device tester capable of testing for proper operation of reduced power states in memory devices. The memory device tester can include a processor or a state machine, each configured to send commands to the memory device, and to compare results. An example of a memory device that can be tested by the memory device tester is a Direct Rambus Dynamic Random Access Memory (DRDRAM). The described processing systems and other circuits can test a DRDRAM for proper operation in a standby (STBY) state. When the DRDRAM is in STBY, the column decoder is shut off to conserve power, and the DRDRAM should not respond to column packets on the column control bus. The method and apparatus provide for testing that the column decoder is shut off when in STBY with no banks active, which is the recommended usage pattern for the part.

Abstract: A memory device tester capable of testing for proper operation of reduced power states in memory devices. The memory device tester can include a processor or a state machine, each configured to send commands to the memory device, and to compare results. An example of a memory device that can be tested by the memory device tester is a Direct Rambus Dynamic Random Access Memory (DRDRAM). The described processing systems and other circuits can test a DRDRAM for proper operation in a standby (STBY) state. When the DRDRAM is in STBY, the column decoder is shut off to conserve power, and the DRDRAM should not respond to column packets on the column control bus. The method and apparatus provide for testing that the column decoder is shut off when in STBY with no banks active, which is the recommended usage pattern for the part.

Abstract: A memory device tester capable of testing for proper operation of reduced power states in memory devices. The memory device tester can include a processor or a state machine, each configured to send commands to the memory device, and to compare results. An example of a memory device that can be tested by the memory device tester is a Direct Rambus Dynamic Random Access Memory (DRDRAM). The described processing systems and other circuits can test a DRDRAM for proper operation in a standby (STBY) state. When the DRDRAM is in STBY, the column decoder is shut off to conserve power, and the DRDRAM should not respond to column packets on the column control bus. The DRDRAM Specification suggests that the DRDRAM be put in the STBY state with no banks active. The method and apparatus provide for testing that the column decoder is shut off when in STBY with no banks active, which is the recommended usage pattern for the part.

Abstract: A CMOS sense amplifier circuit for a dynamic read/write memory employs cross-coupled N-channel transistors and cross-coupled P-channel transistors, returned to the voltage supply and ground through transistors activated by sense clocks. The differential inputs of the sense amplifier are connected to the bit lines through coupling transistors which are held on when the word line and dummy line go high, then are shut off while the sense amplifier is activated by the sense clocks; the coupling transistors are then turned on for selected columns before being turned on for non-selected columns. The current needed to charge and discharge the bit lines is thus spread out, and the peak current is decreased.

Abstract: A test validation process for a semiconductor device applies signals indicating a test mode to the semiconductor device. The device produces output signals and the output signals are read to determine whether the device is in the indicated test mode. The test mode is conducted by operating the device. The output signals are read upon completion of the test mode to determine if the device is still in the indicated test mode. The test validation method is useful for memory chips and particularly Dynamic Random Access Memory, DRAM, devices that are burn-in stress tested.

Abstract: A CMOS sense amplifier circuit for a dynamic read/write memory employs cross-coupled N-channel transistors and cross-coupled P-channel transistors, returned to the voltage supply and ground through transistors activated by sense clocks. The differential inputs of the sense amplifier are connected to the bit lines through coupling transistors which are held on when the word line and dummy line go high, then are shut off while the sense amplifier is activated by the sense clocks; the coupling transistors are then turned on for selected columns before being turned on for non-selected columns. The current needed to charge and discharge the bit lines is thus spread out, and the peak current is decreased.

Abstract: A CMOS sense amplifier circuit for a dynamic read/write memory employs cross-coupled N-channel transistors and cross-coupled P-channel transistors, returned to the voltage supply and ground through two separate sets of P and N channel transistors selectively activated by sense clocks. The return transistors are activated for either fast or slow sensing, depending upon the address input. The selected columns are sensed at maximum speed, and non-selected columns which are only being refreshed are sensed at a slower speed. A large return transistor is switched into the circuit only for fast sensing, and other smaller transistors perform the slow sense function with high resistance returns to the supply so peak current is lower. The current needed to charge and discharge the bit lines is thus spread out, and the peak current is decreased.

Abstract: A CMOS sense amplifier for a dynamic read/write memory employs a latch circuit with cross-coupled N-channel transistors and cross-coupled P-channel transistors, returned to the voltage supply and ground through P and N channel transistors selectively activated by sense clocks. Differential inputs of the sense amplifier are connected to the bit lines. The N-channel transistors are employed for initial sensing, and then both N-channel and P-channel transistors in sequential order for amplification and restoring the 1-level. This results in better balance, and smaller N and P channel latch transistors may be used, saving area, saving power and increasing speed.

Abstract: A semiconductor dynamic read/write memory circuit using one-transistor storage cells and balanced bit lines with differential sense amplifiers employs dummy capacitors which are the same size as the storage capacitors. The dummy cell produces a signal on the bit line half that of the storage cell due to a level-shift circuitry connected to the dummy cells. The dummy capacitor is precharged to a reference voltage, and at the beginning of an active cycle the dummy capacitor is charge-shared with another capacitance of the same size, to change the reference level. The net signal is thus equal to that of a capacitor one-half the size of the storage capacitors.

Abstract: A CMOS sense amplifier for a dynamic read/write memory employs a latch circuit with cross-coupled N-channel transistors and cross-coupled P-channel transistors, returned to the voltage supply and ground through P and N channel transistors selectively activated by sense clocks. Differential inputs of the sense amplifier are connected to the bit lines. The N-channel transistors are employed for initial sensing, and then both N-channel and P-channel transistors in sequential order for amplification and restoring the I-level. This results in better balance, and smaller N and P channel latch transistors may be used, saving area, saving power and increasing speed.