A peak detector includes an asymmetrical latch having a first input and a second input; and a CMOS converter having a first input coupled to a first output of the asymmetrical latch, a second input coupled to a second output of the asymmetrical latch, and an output.

A circuit includes a gain stage, first and second amplifiers, and a comparison circuit. The gain stage has an input and an output. The first amplifier has an input and an output. The input of the first amplifier is coupled to the input of the gain stage. The second amplifier has an input and an output. The input of the second amplifier is coupled to the output of the gain stage. The comparison circuit is coupled to the outputs of the first and second amplifiers. The comparison circuit is configured to compare signals on the outputs of the first and second amplifiers and to generate a fault flag signal responsive to the output signal from the first amplifier being different than the output signal from the second amplifier.

A circuit includes a gain stage, first and second amplifiers, and a comparison circuit. The gain stage has an input and an output. The first amplifier has an input and an output. The input of the first amplifier is coupled to the input of the gain stage. The second amplifier has an input and an output. The input of the second amplifier is coupled to the output of the gain stage. The comparison circuit is coupled to the outputs of the first and second amplifiers. The comparison circuit is configured to compare signals on the outputs of the first and second amplifiers and to generate a fault flag signal responsive to the output signal from the first amplifier being different than the output signal from the second amplifier.

A peak detector includes an asymmetrical latch having a first input and a second input; and a CMOS converter having a first input coupled to a first output of the asymmetrical latch, a second input coupled to a second output of the asymmetrical latch, and an output.

An embodiment includes a track and hold amplifier device. A device may include an emitter follower transistor coupled to each of an input and an output. The device may also include a charging node coupled between the output and a voltage supply, wherein the charging node is also coupled to the input via the emitter follower transistor. Further, the device may include a cascode switch coupled to each of the input and the output. The cascode switch may be configured to cause the emitter follower transistor to operate in a conductive state and charge the charging node during a track mode. The cascode switch may also be configured to cause the emitter follower transistor to operate in a non-conductive state to isolate the charging node from the input during a hold mode. The cascode switch may include a MOS-HBT transistor combination operating in class AB mode.

A low dropout regulator includes an output circuit and an amplifier. The output circuit includes a signal input end configured to receive an input voltage and a signal output end configured to output an output voltage. The amplifier includes a first stage amplifier circuit, a second stage amplifier circuit, a first feedback circuit and a second feedback circuit. The first stage amplifier circuit includes a positive output end and a negative output end. The second stage amplifier circuit includes an input end and an output end, wherein the input end and the positive output end are coupled at a first node, and the output end is coupled to the output circuit. The first feedback circuit is coupled between the negative output end and the output end. The second feedback circuit is coupled between the first node and the output end.

Provided is a track-and-hold circuit capable of reducing the power consumption of a differential amplifier circuit while preserving the broadband nature (without narrowing the bandwidth). In the track-and-hold circuit 1 including a differential amplifier circuit 10, a switch circuit 20, and a hold capacitor C.sub.21, the differential amplifier circuit 10 includes a first resistor R.sub.11 having one end connected to a collector electrode of a first transistor Q.sub.11 constituting a differential pair, a second resistor R.sub.12 having one end connected to the collector electrode of a second transistor Q.sub.12 constituting the differential pair, and a third resistor R.sub.13 to which the other end of the first resistor R.sub.11 and the other end of the second resistor R.sub.12 are connected and which is connected between the other ends and a power supply V.sub.CC.

An amplifier circuit includes a first cascode transistor and a second cascade transistor, the first cascade transistor being electrically connected between a first transistor and a first load circuit, the second cascode transistor being electrically connected between a second transistor and a second load circuit. The amplifier circuit includes a first shunt transistor and a second shunt transistor, the first shunt transistor being electrically connected between the first transistor and a first emitter-follower circuit, the second shunt transistor being electrically connected between the second transistor and a second emitter-follower circuit. A differential current signal includes a first differential current and a second differential current, the first differential current flowing through the first cascode transistor and the second cascode transistor, and a second differential current flowing through the first shunt transistor and the second shunt transistor.

Multifunctional RF limiting amplifiers having various configurations and functions are disclosed. In a first configuration, the RF limiting amplifier includes an active load output circuit that allows one to adjust the output impedance based upon the anticipated connected load impedance. In a second configuration, the RF limiting amplifier includes a pair of emitter-followers to buffer the output of a first stage, allowing the RF limiting amplifier to drive one or more second stages. A third configuration includes a pair of RF limiting amplifiers with their outputs mixed to implement a down conversion function. The third configuration may be used to drive dual SAW resonators for detecting the presence of biological or chemical agents. The RF limiting amplifier may be implemented in either bipolar junction transistors or CMOS transistors.

Provided is a an electronic system (1) comprising a plurality of sub blocks (21, 22, . . . ), a differential amplifier (3), a voltage regulation loop comprising a first transistor (40) and a variable resistor (5), and a plurality of additional transistors (41, 42, . . . ). The input reference voltage (VRF) and the variable resistor are configured such that a first sub block (21) is supplied with its required power supply output voltage (VDD1) by the transistor to which it is connected. The amplifier is configured to output on each of its outputs a power supply reference voltage (VG1, VG2 . . . ) such that each sub block (22, . . . ) other than the first sub block is supplied with its required power supply output voltage (VDD2 . . . ) by the transistor to which it is connected.