IDT FemtoClock Clock-Frequency Synthesizers
IDT FemtoClock® Clock-Frequency Synthesizers are advanced, high-performance clock-frequency synthesizers. Employing a simple, low-cost, fundamental-mode quartz crystal as the low frequency reference these devices synthesize high quality clock signals with less than 0.5 ps of RMS phase noise, up to 1.3 GHz. FemtoClock devices are fully customizable, stand-alone solutions that generate reference frequencies allowing them to replace crystal and SAW oscillators in high-performance applications. This family of devices is often used to replace third overtone and high frequency fundamental (HFF, inverted mesa) crystal oscillators or expensive surface acoustic wave (SAW) oscillators.
IDT IDTP9030 / IDT9020 Qi-Certified Wireless Power Transmitter and Receiver
Integrated Device Technology IDTP9030 is the industry's most highly integrated Qi-certified single-chip wireless power transmitter. IDT IDTP9030 wireless power transmitter IC has received full Qi certification by the Wireless Power Consortium (WPC). IDTP9030 wireless power transmitter is interoperable with any device meeting the WPC Qi standard, making this IDT single-chip IC ideal for designers of compact and cost-efficient Qi-compliant charging stations. Value-added proprietary features include advanced multi-layered Foreign Object Detection for safety, two-way secure authentication between base and mobile, and power delivery up to 7.5W for faster charging times. Complementing the IDTP9030 transmitter is the IDTP9020 high-efficiency single-chip wireless power receiver. This IDT receiver integrates a high-efficiency synchronous full bridge rectifier, high efficiency synchronous buck converter, and control circuits used to modulate the load to transmit WPC compliant message packets to the transmitter station to optimize power delivery. Both the IDTP9030 and IDTP9020 are capable of multi-mode operation, supporting the Qi standard and proprietary formats. Built-in protocol detection enables dynamic switching between Qi and proprietary modes, creating seamless transitions and a trouble-free user experience. Evaluation kits are available for quick and easy evaluation of the IDTP9030 transmitter and IDTP9020 receiver.
IDT 9FGVxxx / 9DBVxxx PCI Express® Timers
Integrated Device Technology 9FGVxxx / 9DBVxxx PCI Express® Timers comprise the world's lowest-power PCI Express timing family. These IDT buffers and synthesizers offer unprecedented power savings and integration for communications, computing, and consumer markets. IDT 9FGVxxx synthesizers and 9DBVxxx buffers consume less than 50mW of power - less than one-tenth the power required by previous solutions. The ultra-low power consumption reduces heat dissipation to ease cooling requirements in large-scale cloud computing applications. These clock synthesizers and buffers are available with either integrated or external termination on the differential outputs. All of these IDT devices meet PCIe Gen 1, Gen 2, and Gen 3 performance requirements, allowing for long-lifecycle designs that customers can re-use through several generations of their products. Most members of this new timing family feature a selectable SMBus address so that multiple devices can seamlessly share the same SMBus segment without the cumbersome additional logic that is often required with other solutions.
IDT 8546-01 Low Skew, 1-to-6 Crystal-to-LVDS Fanout Buffer
Integrated Device Technology 8546-01 is a low skew, high performance 1-to-6 Crystal Oscillator-to-LVDS fanout buffer. IDT 8546-01 has selectable crystal, single-ended, or differential clock inputs. The single-ended clock input accepts LVCMOS or LVTTL input levels and translate them to LVDS levels. The CLK1, nCLK1 pair can accept most standard differential input levels. The output enable is internally synchronized to eliminate runt pulses on the outputs during asynchronous assertion / deassertion of the clock enable pin. Guaranteed output and part-to-part skew characteristics make the 8546-01 ideal for applications demanding well-defined performance and repeatability.
IDT 5V49EE EEPROM Programmable Clock Generators
Integrated Device Technology 5V49EE programmable clock generators are designed for high performance data-communications, telecommunications, consumer, and networking applications. These IDT devices have four internal PLLs, each individually programmable, allowing for four unique non-integer-related frequencies. The frequencies are generated from a single reference clock that can come from one of the two redundant clock inputs. Automatic or manual switchover function allows any one of the redundant clocks to be selected during normal operation. IDT 5V49EE programmable clock generators are in-system, programmable and can be programmed through the use of I²C interface. An internal EEPROM allows the user to save and restore the configuration of the device without having to reprogram it on power-up.
IDT 85102 / 85104 / 85108 HCSL Buffers
Integrated Device Technology 85102 / 85104 / 85108 HCSL Buffers are low skew, high performance members of the HiPerClockS™ family of high-performance clock solutions. IDT 85102 is a 1-to-2 Differential-to-HCSL fanout buffer with a differential clock input. The CLK0, nCLK0 input pair can accept most standard differential input levels. The clock enable is internally synchronized to eliminate runt clock pulses on the output during asynchronous assertion/deassertion of the clock enable pin. IDT 85104 is a 1-to-4 Differential/LVCMOS-to-0.7V HCSL fanout buffer with two selectable clock inputs. The CLK0, nCLK0 pair can accept most standard differential input levels. The single-ended CLK1 can accept LVCMOS or LVTTL input levels. IDT 85108 is a 1-to-8 Differential-to-0.7V HCSL clock distribution chip that can accept most differential input levels and translates them to 3.3V HCSL output levels. 85108 provides a low power, low noise, low skew, point-to-point solution for distributing HCSL clock signals. Guaranteed output and part-to-part skew characteristics make IDT 85102 / 85014 / 85108 devices ideal for applications demanding well-defined performance and repeatability.