Apparatus and methods for multiphase clock generation are provided herein. In certain embodiments, a multiphase clock generator includes a first clock buffer that generates a first output clock signal based on a first input clock signal, a second clock buffer that generates a second output clock signal based on a second input clock signal, and a first clock interpolation circuit that generates a third output clock signal based on interpolating the first input clock signal and the second input clock signal. The first clock interpolation circuit generates the third output clock signal based on multiplying the first input clock signal by a first adjustable current to generate a first multiplied current, multiplying the second input clock signal by a second adjustable current to generate a second multiplied current, combining the first multiplied current and the second multiplied current to generate a combined current, and integrating the combined current.

Apparatus and methods for multiphase clock generation are provided herein. In certain embodiments, a multiphase clock generator includes a first clock buffer that generates a first output clock signal based on a first input clock signal, a second clock buffer that generates a second output clock signal based on a second input clock signal, and a first clock interpolation circuit that generates a third output clock signal based on interpolating the first input clock signal and the second input clock signal. The first clock interpolation circuit generates the third output clock signal based on multiplying the first input clock signal by a first adjustable current to generate a first multiplied current, multiplying the second input clock signal by a second adjustable current to generate a second multiplied current, combining the first multiplied current and the second multiplied current to generate a combined current, and integrating the combined current.

An integrated interface of a detector module of a Positron Emission Tomography (PET) may include a power module, a clock module, a synchronization module, and a communication module. In one embodiment, Gigabit Ethernet, 10G Ethernet, Fast Ethernet (100M), 10M Ethernet or custom speed Ethernet based solution can be used in the communication module. In the power module, the power is can be transmitted by standard PoE (Power over Ethernet) method, while the clock can be recovered from Ethernet in the clock module. In the synchronization module, in one embodiment, the synchronization can be done through a dedicated package and/or IEEE1588. The integrated interface can be implemented in other systems. For example, it can be used in a gamma camera system or gamma probe, especially a dynamic gamma camera or handheld gamma camera.

An integrated interface of a detector module of a Positron Emission Tomography (PET) may include a power module, a clock module, a synchronization module, and a communication module. In one embodiment, Gigabit Ethernet, 10G Ethernet, Fast Ethernet (100M), 10M Ethernet or custom speed Ethernet based solution can be used in the communication module. In the power module, the power is can be transmitted by standard PoE (Power over Ethernet) method, while the clock can be recovered from Ethernet in the clock module. In the synchronization module, in one embodiment, the synchronization can be done through a dedicated package and/or IEEE1588. The integrated interface can be implemented in other systems. For example, it can be used in a gamma camera system or gamma probe, especially a dynamic gamma camera or handheld gamma camera.

A circuit interface includes one or more processors that generate opcodes, a plurality of interface control circuits, each including a respective processing element responsive to the opcodes generated by one or more processors. Each interface control circuit corresponds to a respective link of a plurality of links of a device-to-device interface (DDI), and each link of the plurality of links of the DDI is for transmitting or receiving signals from one or more sources or one or more destinations external to the circuit.

A circuit interface includes one or more processors that generate opcodes, a plurality of interface control circuits, each including a respective processing element responsive to the opcodes generated by one or more processors. Each interface control circuit corresponds to a respective link of a plurality of links of a device-to-device interface (DDI), and each link of the plurality of links of the DDI is for transmitting or receiving signals from one or more sources or one or more destinations external to the circuit.

Embodiments of a reference path circuit and communication device are generally described herein. The reference path circuit may include an injection locked multiplier (ILM) and a group of one or more buffer amplifiers. The ILM may receive a sinusoidal reference signal from a reference oscillator at a reference frequency. The ILM may generate a sinusoidal ILM output signal at an ILM output frequency that is based on an integer multiple of the reference frequency. The integer multiple of the reference frequency may be within a locking range of the ILM that may be based on a resonant frequency of the ILM. The group of one or more buffer amplifiers may generate an output clock signal for input to the frequency synthesizer. The output clock signal may be based on a sign function of the ILM output signal.

Embodiments of a reference path circuit and communication device are generally described herein. The reference path circuit may include an injection locked multiplier (ILM) and a group of one or more buffer amplifiers. The ILM may receive a sinusoidal reference signal from a reference oscillator at a reference frequency. The ILM may generate a sinusoidal ILM output signal at an ILM output frequency that is based on an integer multiple of the reference frequency. The integer multiple of the reference frequency may be within a locking range of the ILM that may be based on a resonant frequency of the ILM. The group of one or more buffer amplifiers may generate an output clock signal for input to the frequency synthesizer. The output clock signal may be based on a sign function of the ILM output signal.

The present application is directed to signal delay control and related apparatuses, systems, and methods. An apparatus includes delay elements and control circuitry electrically connected to the delay elements. The delay elements are configured to receive skewed data signals and delay codes indicating delay quantities. The delay elements are also configured to provide delayed data signals delayed relative to the skewed data signals by the delay quantities. The control circuitry is configured to provide the delay codes, which are selected to reduce a timing skew of the delayed data signals relative to a timing skew of the skewed data signals. A system includes a first device, a second device including the apparatus, and transmission lines electrically connected between the first device and the second device. A method includes calibrating the delay codes.

The present application is directed to signal delay control and related apparatuses, systems, and methods. An apparatus includes delay elements and control circuitry electrically connected to the delay elements. The delay elements are configured to receive skewed data signals and delay codes indicating delay quantities. The delay elements are also configured to provide delayed data signals delayed relative to the skewed data signals by the delay quantities. The control circuitry is configured to provide the delay codes, which are selected to reduce a timing skew of the delayed data signals relative to a timing skew of the skewed data signals. A system includes a first device, a second device including the apparatus, and transmission lines electrically connected between the first device and the second device. A method includes calibrating the delay codes.