Abstract: A sense amplifier (100) useable with memories having multi-level memory cells (105) includes a cascode device (135) coupled to the cell (105) to increase sense amplifier resolution. In a pre-charge mode, the sense amplifier (100) is configured to pre-charge a bit-line (140) of the cell (105) to reduce time required to read the cell. The pre-charge mode may include a unity gain buffer (175) to which a reference voltage is applied, and a switch (165, 170). The switch (165, 170) couples the buffer to the cascode device (135) to pre-charge the bit-line (140), and decouples the buffer from the device to enable the amplifier (100) to develop a voltage signal representing data stored in the cell. The sense amplifier (100) can be re-configured in a regeneration mode to amplify the voltage signal, to conserve chip space, and reduce cost and errors in reads.

Abstract: A sense amplifier (100) useable with memories having multi-level memory cells (105) includes a cascode device (135) coupled to the cell (105) to increase sense amplifier resolution. In a pre-charge mode, the sense amplifier (100) is configured to pre-charge a bit-line (140) of the cell (105) to reduce time required to read the cell. The pre-charge mode may include a unity gain buffer (175) to which a reference voltage is applied, and a switch (165, 170). The switch (165, 170) couples the buffer to the cascode device (135) to pre-charge the bit-line (140), and decouples the buffer from the device to enable the amplifier (100) to develop a voltage signal representing data stored in the cell. The sense amplifier (100) can be re-configured in a regeneration mode to amplify the voltage signal, to conserve chip space, and reduce cost and errors in reads.

Abstract: Driver (100) and method are provided for driving capacitive load (120) that achieve an improved response time without increasing power consumption of the driver. Driver (100) has load buffer (105) with an input (110) for receiving an input voltage (VIN), and an output 115 for coupling an output voltage (VOUT) to load 120. VOUT is driven between a first voltage level (V1) and a second voltage level (V2) in response to changes in VIN. Driver (100) also has reserve circuit (125) with capacitor (130), reserve buffer (135), switch (140) for coupling the capacitor to capacitive load (120) and controller (145) for operating the switch. Reserve buffer (135) has an input (150) for receiving an input voltage (VRES—IN), and an output (155) for coupling an output voltage (VRES—OUT) to capacitor (130) to charge the capacitor. Controller (145) is configured to operate switch (140) to couple capacitor (130) to capacitive load (120) when VOUT is being driven between V1 and V2.

Abstract: Driver (100) and method are provided for driving capacitive load (120) that achieve an improved response time without increasing power consumption of the driver. Driver (100) has load buffer (105) with an input (110) for receiving an input voltage (VIN), and an output 115 for coupling an output voltage (VOUT) to load 120. VOUT is driven between a first voltage level (V1) and a second voltage level (V2) in response to changes in VIN. Driver (100) also has reserve circuit (125) with capacitor (130), reserve buffer (135), switch (140) for coupling the capacitor to capacitive load (120) and controller (145) for operating the switch. Reserve buffer (135) has an input (150) for receiving an input voltage (VRES—IN), and an output (155) for coupling an output voltage (VRS—OUT) to capacitor (130) to charge the capacitor. Controller (145) is configured to operate switch (140) to couple capacitor (130) to capacitive load (120) when VOUT is being driven between V1 and V2.