Embodiments of the present application provide an oscillator and a clock generation circuit. The oscillator includes: a first ring topology, including a plurality of first inverters connected end to end, and configured to transmit an oscillation signal at a first transmission speed; and a second ring topology, including a plurality of second inverters connected end to end, and configured to transmit the oscillation signal at a second transmission speed, wherein the present application, the first ring topology is electrically connected to the second ring topology, and the second transmission speed is less than the first transmission speed.

A clock source includes a comparator having a positive comparator input, a negative comparator input, a proportional to absolute temperature (PTAT) PMOS bias input, a PTAT NMOS bias input, and a comparator output, a resonator element, series and feedback resistors and other passive components coupled between the comparator output and the negative comparator input to generate a signal with approximately constant gain and frequency at the comparator output, and a PTAT bias circuit coupled to the comparator's PTAT PMOS and NMOS bias inputs, and configured to drive the PTAT PMOS bias input and the PTAT NMOS bias input to maintain approximately constant gain and frequency over the operating temperature range of the clock source.

There is provided a semiconductor device comprising: a first inverter circuit (11) connected in parallel to a crystal vibrating element (X1); a second inverter circuit (12) connected to the first inverter circuit (11) so as to share an input therewith, and outputting an oscillation signal; and a wave filter (14) connected to the second inverter circuit (12) and having a passband that is determined in advance and includes an oscillation frequency of the oscillation signal.

A semiconductor device including a first inverter circuit connected in parallel to a crystal vibrating element; a second inverter circuit connected to the first inverter circuit so as to share an input therewith, and outputting an oscillation signal; and a wave filter connected to the second inverter circuit and having a passband that is determined in advance and includes an oscillation frequency of the oscillation signal.

An oscillator circuit arrangement comprises an inverter having input and output terminals that are to be connected to a crystal device. An automatic gain control device controls a current source that supplies current to the inverter. First and second diode devices having different orientation are connected between the input and the output of the inverter. The oscillator consumes low power and has a fast recovery time after an electromagnetic interference event. The oscillator can be used in electronic labels.

A low power crystal oscillator circuit has a high power part and a low power part. Crystal oscillation is initialized using the high power part. An automatic amplitude control circuit includes a current subtractor that decreases current in the high power part as an amplitude of the crystal oscillation increases. A current limiting circuit may limit current in the low power part in order to further reduce power consumption by the low power crystal oscillator circuit. Additionally, an automatic amplitude detection circuit may turn off the high power part after the amplitude of the crystal oscillation reaches a predetermined level in order to further reduce power consumption of the low power crystal oscillator circuit, and may turn back on the high power part after the amplitude of the crystal oscillation reaches a second predetermined level in order to maintain the crystal oscillation.

Embodiments of the present application provide an oscillator and a clock generation circuit. The oscillator includes: a first ring topology, including a plurality of first inverters connected end to end, and configured to transmit an oscillation signal at a first transmission speed; and a second ring topology, including a plurality of second inverters connected end to end, and configured to transmit the oscillation signal at a second transmission speed, wherein the present application, the first ring topology is electrically connected to the second ring topology, and the second transmission speed is less than the first transmission speed.

An apparatus includes: a first inverter configured to receive a first clock signal and output a second clock signal, wherein an input pin, an output pin, a power pin, and a ground pin of the first inverter connect to the first clock signal, the second clock signal, a first source node, and a second source node, respectively; a second inverter configured to receive the second clock signal and output a third clock signal, wherein an input pin, an output pin, a power pin, and a ground pin of the second inverter connect to the second clock signal, the third clock signal, the first source node, and the second source node, respectively; a first resistor connected to a first DC (direct-current) voltage to the first source node; and a second resistor connected to a second DC voltage to the second source node.

An oscillator circuit arrangement comprises an inverter having input and output terminals that are to be connected to a crystal device. An automatic gain control device controls a current source that supplies current to the inverter. First and second diode devices having different orientation are connected between the input and the output of the inverter. The oscillator consumes low power and has a fast recovery time after an electromagnetic interference event. The oscillator can be used in electronic labels.

A ring oscillator circuit is formed by series connected inverter circuits with a feedback loop. The inverter circuits are source biased with an oscillator voltage. A resistor-less bias current generator circuit generates a bias current for application to a replica inverter circuit to generate a bias voltage. A scaling circuit operates to scale the bias voltage by a selectable scaling factor to generate the oscillator voltage in a manner which balances a mobility effect of the inverter circuits within the ring oscillator circuit against a threshold voltage effect of the inverter circuits within the ring oscillator circuit. The clock signal output from the ring oscillator circuit has a frequency which is independent of process, voltage and temperature (PVT) spread.