Abstract: A measurement circuit and method for measuring a quiescent current of a circuit under test are provided. The measurement circuit comprises: a comparator having a first input terminal for receiving a reference voltage, a second input terminal coupled to the circuit under test, and an output terminal; a current source having a first terminal coupled to a first power supply voltage terminal, and a second terminal for providing a current to the circuit under test; a first switch having a first terminal coupled to the second terminal of the current source, a second terminal coupled to the circuit under test, and a control terminal coupled to the output terminal of the comparator; and a first counter having a first input terminal coupled to the output terminal of the comparator, a second input terminal for receiving a clock signal, and an output terminal for providing a first counter value associated with the quiescent current.

Abstract: An indication that a power supply is ramped up to a threshold level is received. A circuit is woken up in response to receiving the indication if a control field of configuration information is in a first state, and the circuit is not woken up in response to receiving the indication if the control field of configuration information is in a second state.

Abstract: A data converter for converting analog signals to digital signals, or for converting digital signals to analog signals is provided. In one embodiment, a production self-test is provided. In one embodiment, a high-speed lower-resolution method or mode for a data converter is provided. In one embodiment, a differential data converter with a more stable comparator common mode voltage is provided. In one embodiment, the input range of a digitally calibrated data converter is provided and maintained so that there is no loss in input range due to the calibration. In one embodiment, digital post-processing of an uncalibrated result using a previously stored calibration value is provided.

Abstract: A data converter for converting analog signals to digital signals, or for converting digital signals to analog signals is provided. In one embodiment, a production self-test is provided. In one embodiment, a high-speed lower-resolution method or mode for a data converter is provided. In one embodiment, a differential data converter with a more stable comparator common mode voltage is provided. In one embodiment, the input range of a digitally calibrated data converter is provided and maintained so that there is no loss in input range due to the calibration. In one embodiment, digital post-processing of an uncalibrated result using a previously stored calibration value is provided.

Abstract: A data converter for converting analog signals to digital signals, or for converting digital signals to analog signals is provided. In one embodiment, a production self-test is provided. In one embodiment, a high-speed lower-resolution method or mode for a data converter is provided. In one embodiment, a differential data converter with a more stable comparator common mode voltage is provided. In one embodiment, the input range of a digitally calibrated data converter is provided and maintained so that there is no loss in input range due to the calibration. In one embodiment, digital post-processing of an uncalibrated result using a previously stored calibration value is provided.

Abstract: A data converter for converting analog signals to digital signals, or for converting digital signals to analog signals is provided. In one embodiment, a production self-test is provided. In one embodiment, a high-speed lower-resolution method or mode for a data converter is provided. In one embodiment, a differential data converter with a more stable comparator common mode voltage is provided. In one embodiment, the input range of a digitally calibrated data converter is provided and maintained so that there is no loss in input range due to the calibration. In one embodiment, digital post-processing of an uncalibrated result using a previously stored calibration value is provided.

Abstract: A data converter for converting analog signals to digital signals, or for converting digital signals to analog signals is provided. In one embodiment, a production self-test is provided. In one embodiment, a high-speed lower-resolution method or mode for a data converter is provided. In one embodiment, a differential data converter with a more stable comparator common mode voltage is provided. In one embodiment, the input range of a digitally calibrated data converter is provided and maintained so that there is no loss in input range due to the calibration. In one embodiment, digital post-processing of an uncalibrated result using a previously stored calibration value is provided.

Abstract: A data converter for converting analog signals to digital signals, or for converting digital signals to analog signals is provided. In one embodiment, a production self-test is provided. In one embodiment, a high-speed lower-resolution method or mode for a data converter is provided. In one embodiment, a differential data converter with a more stable comparator common mode voltage is provided. In one embodiment, the input range of a digitally calibrated data converter is provided and maintained so that there is no loss in input range due to the calibration. In one embodiment, digital post-processing of an uncalibrated result using a previously stored calibration value is provided.

Abstract: A circuit includes an input terminal, an output terminal and a latch. The input terminal receives an input signal. The latch is programmable with a value. The latch communicates the input signal to the output terminal in response to the circuit not being in a sleep mode and in response to the circuit being in the sleep mode, furnishes a second signal to the output terminal indicative of the value.

Abstract: An integrated circuit has an internal oscillator circuit for being connected to an external frequency source such as a crystal or a ceramic resonator. The internal oscillator circuit has an inverting amplifier across the frequency source terminals to establish an oscillation there. One terminal of the frequency source is coupled to one input of the comparator and to a second input of the comparator through a low pass filter. Coupling the output of the low pass filter to the second input of the comparator is for preventing a DC offset from developing between the two inputs of the comparator. The other terminal of the frequency source is coupled to the second input of the comparator through a high pass filter. The high pass filter provides the comparator with a larger voltage differential to increase noise margin. Noise margin is further improved by allowing an increase in hysteresis in the comparator.

Abstract: Circuits in a processor may provide an indication that power supplies are ready when waking from a reduced power state. The processor may include timers to measure a period of time, and may utilize voltage detectors to detect the voltages on the power supplies. A control register in the processor may influence the operation.

Abstract: Power saving method is achieved by weakly holding a signal line in its last in time state, which is responsive to and may be overcome by the state of an external signal. During sleep mode, the weakly held signal line state tracks and holds the external signal using alternatively a controllable weak pull-up or pull-down device, such that weakly held state may be driven to a different state by the external driving signal with slight power consumption. When sleep mode is off, the keeper function is disabled and the signal line maybe driven alternatively internally or externally depending upon the state of an enable line.

Abstract: Power saving method is achieved by weakly holding a signal line in its last in time state, which is responsive to and may be overcome by the state of an external signal. During sleep mode, the weakly held signal line state tracks and holds the external signal using alternatively a controllable weak pull-up or pull-down device, such that weakly held state may be driven to a different state by the external driving signal with slight power consumption. When sleep mode is off, the keeper function is disabled and the signal line maybe driven alternatively internally or externally depending upon the state of an enable line.

Abstract: A circuit includes an input terminal, an output terminal and a latch. The input terminal receives an input signal. The latch is programmable with a value. The latch communicates the input signal to the output terminal in response to the circuit not being in a sleep mode and in response to the circuit being in the sleep mode, furnishes a second signal to the output terminal indicative of the value.

Abstract: An integrated circuit may be initialized by determining that the supply voltage is ramping up and resetting logic in the integrated circuit to a predetermined initial state using a reset signal. After the logic is determined to be in its initial state and the supply voltage is established, the reset signal may be latched off.

Abstract: An integrated circuit may be initialized by determining that the supply voltage is ramping up and resetting logic in the integrated circuit to a predetermined initial state using a reset signal. After the logic is determined to be in its initial state and the supply voltage is established, the reset signal may be latched off.

Abstract: Power saving method is achieved by weakly holding a signal line in its last in time state, which is responsive to and may be overcome by the state of an external signal. During sleep mode, the weakly held signal line state tracks and holds the external signal using alternatively a controllable weak pull-up or pull-down device, such that weakly held state may be driven to a different state by the external driving signal with slight power consumption. When sleep mode is off, the keeper function is disabled and the signal line maybe driven alternatively internally or externally depending upon the state of an enable line.

Abstract: A circuit includes an input terminal, an output terminal and a latch. The input terminal receives an input signal. The latch is programmable with a value. The latch communicates the input signal to the output terminal in response to the circuit not being in a sleep mode and in response to the circuit being in the sleep mode, furnishes a second signal to the output terminal indicative of the value.

Abstract: A system comprising a supply voltage isolation module (50), and a battery detector (52), both responsive to a battery pin (41). The system further including a voltage detection module (54) responsive to a voltage supply pin (42), where the voltage detection module (54) compares a supply voltage from the voltage supply pin (42) to a threshold. The system also including control logic (56) responsive to the battery detector (52) and the voltage detection module (54). Also disclosed are methods for responding to connection of a battery (36) to a logic device (12), placing a logic device (12) into a low power state in response to connection of a battery (36) to the logic device (12), and detecting a battery condition for a logic device (12) having a battery pin (41).

Abstract: An integrated circuit containing a data processing system with a number of external peripheral pins utilizes the peripheral pins for both testing the corresponding peripherals and for parallel testing of other complex functions in a MCU. The MCU has a plurality of test modes that can be selected, with different peripheral pins being connected to a test circuit depending on which test mode is selected. This allows testing of peripherals via their corresponding pins, as well as other complex functions without the necessity of having dedicated test pins.