This block diagram displays a typical circuit design for a “Resonant Battery Charger” (a large, industrial type Resonant Battery Charger).

This block diagram displays a typical circuit design for a “High-Frequency Battery Charger” (a large, industrial type High-Frequency Battery Charger). High-Frequency Battery Chargers can generally charge batteries more quickly and with higher power transfer efficiency than Resonant Battery Chargers.

This block diagram depicts a typical RF amplifier used to excite a laser. This amplifier could have an output power in the range of 20 Watts up to 1,200 Watts as it uses only one push-pull amplifier (LDMOS is recommended).

This block diagram depicts a High-Power RF amplifier used to excite a laser. This amplifier could have an output power well above 1,200 Watts (as it uses at least two, and possibly more, push-pull amplifier packages).

This block diagram depicts both discrete and integrated GPS Receiver Designs. Multiple configurations are shown for the front-end.

This block diagram depicts a conceptual IED Jammer. It is not based on any actual, implemented design, but rather is intended to facilitate the design planning stage for an IED Jamming System. All information included here is unclassified.

This block diagram depicts the main electronic circuit blocks needed to realize the RF portions of a JTRS Radio, which is based on a flexible, software defined architecture. A JTRS radio is considered frequency agile because there may be a requirement for it to be used over several different frequency ranges (and JTRS "waveforms").

This block diagram depicts the main electronic circuit blocks needed to realize the RF Sections of an overall MRI system design. This diagram includes the power amplifier section, the receiver front end section (MRI Coil-LNA-Diode RF components), the Heat Sink section is shown, and the VCO and Frequency Synthesizer blocks as well.

This block diagram focuses in more closely on the MRI coil(s) and the various non-magnetic electronic components needed to realize the RF front end. PIN Diodes, LNAs, Connectors, Cables, Tuning Inductors, Tuning Capacitors, and RF Capacitors are depicted (all non-magnetic versions).

This block diagram focuses in more closely on the very important MRI Power Amplifier electronic components needed to design the amplifier circuit.

Less than 1.2kW RF Power Amplifier (for Plasma RF Generator). Block diagram depicts a typical circuit (simplified); and the RF frequency is normally between 13.56 MHz and 81.36 MHz for this application.

Greater than 1.2kW RF Power Amplifier (for Plasma RF Generator). Block diagram depicts a typical circuit (simplified); and the RF frequency is normally between 13.56 MHz and 81.36 MHz for this application. Wilkinson splitters/combiners are shown as well as a complete “drop-in” pallet amplifier solution.

This block diagram depicts a typical circuit design for ground-based Radar Systems.

This block diagram depicts a typical circuit design for airborne Radar and Systems.

This block diagram depicts a typical circuit design for a ground-based DME - Distance Measuring Equipment – Transponder System.

This block diagram depicts a typical circuit design for an Airborne DME System.

This block diagram depicts a typical circuit (simplified) for a UHF broadcast transmitter covering the 470 - 862 MHz spectrum.

This block diagram displays a typical circuit design for a the power conversion sections of a 3-phase UPS system.

This block diagram depicts a somewhat typical circuit design for a Wireless Infrastructure Base Station (BTS). Included in this design is “Receive Diversity” (2 separate receive antennas and front-ends) as well as sophisticated GPS-based timing/synchronization.