Andy Haase scite author profile

Very low frequency communication systems (3 kHz–30 kHz) enable applications not feasible at higher frequencies. However, the highest radiation efficiency antennas require size at the scale of the wavelength (here, >1 km), making portable transmitters extremely challenging. Facilitating transmitters at the 10 cm scale, we demonstrate an ultra-low loss lithium niobate piezoelectric electric dipole driven at acoustic resonance that radiates with greater than 300x higher efficiency compared to the previous state of the art at a comparable electrical size. A piezoelectric radiating element eliminates the need for large impedance matching networks as it self-resonates at the acoustic wavelength. Temporal modulation of this resonance demonstrates a device bandwidth greater than 83x beyond the conventional Bode-Fano limit, thus increasing the transmitter bitrate while still minimizing losses. These results will open new applications for portable, electrically small antennas.

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Latest Results in SLAC 75 MW PPM Klystrons

Sprehn¹,

Caryotakis²,

Haase³

et al. 2006

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75 MW X-band klystrons utilizing Periodic Permanent Magnet (PPM) focusing have been undergoing design, fabrication and testing at the Stanford Linear Accelerator Center (SLAC) for almost nine years. The klystron development has been geared toward realizing the necessary components for the construction of the Next Linear Collider (NLC). The PPM devices built to date which fit this class of operation consist of a variety of 50 MW and 75 MW devices constructed by SLAC, KEK (Tsukuba, Japan ) and industry. All these tubes follow from the successful SLAC design of a 50 MW PPM klystron in 1996. In 2004 the latest two klystrons were constructed and tested with preliminary results reported at EPAC2004. The first of these two devices was tested to the full NLC specifications of 75 MW, 1.6 microseconds pulse length, and 120 Hz. This 14.4 kW average power operation came with a tube efficiency >50%. The most recent testing of these last two devices will be presented here. Design and manufacturing issues of the latest klystron, due to be tested by the Fall of 2005, are also discussed.

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Design and fabrication of a 94 GHz klystron

Scheitrum¹,

Caryotakis²,

Haase³

et al. 2001

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Increasing klystron efficiency using COM and BAC tuning and application to the 5045 klystron

Jensen

Haase

Jongewaard

et al. 2016

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The klystrino: a high power W-band amplifier

Scheitrum

Arfin²,

James³

et al.

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Andy Haase

A high Q piezoelectric resonator as a portable VLF transmitter

Latest Results in SLAC 75 MW PPM Klystrons

Design and fabrication of a 94 GHz klystron

Increasing klystron efficiency using COM and BAC tuning and application to the 5045 klystron

The klystrino: a high power W-band amplifier

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