Design of a High Temperature GaN-Based VCO for Downhole Communications

Feng, Tianming

20 February 2017

Decreasing reserves of natural resources drives the oil and gas industry to drill deeper and deeper to reach unexploited wells. Coupled with the demand for substantial real-time data transmission, the need for high speed electronics able to operating in harsher ambient environment is quickly on the rise. This paper presents a high temperature VCO for downhole communication system. The proposed VCO is designed and prototyped using 0.25 μm GaN on SiC RF transistor which has extremely high junction temperature capability. Measurements show that the proposed VCO can operate reliably under ambient temperature from 25 °C up to 230 °C and is tunable from 328 MHz to 353 Mhz. The measured output power is 18 dBm with ±1 dB variations over entire covered temperature and frequency range. Measured phase noise at 230 °C is from -121 dBc/Hz to -109 dBc/Hz at 100 KHz offset. / Master of Science / The oil and gas industry are drilling deeper and deeper to reach unexploited wells due to decreasing reserves of easily available natural resources. In addition, high speed electronics able to operating in harsher ambient environment is required to meet the demand for substantial realtime data transmission. This work presents a high temperature VCO for downhole communication system which can meet the requirement aforementioned. The proposed VCO is designed and prototyped to meet the harsh temperature and high speed requirement. Measurements show that, under ambient temperature from 25 °C up to 230 °C, the proposed VCO can operate reliably from 328 MHz to 353 Mhz, as required by the communication system.

high temperature

extreme environment

VCO

GaN on SiC

downhole communications system

A High Temperature Wideband Low Noise Amplifier

Cunningham, Michael Lawrence

27 January 2016

As the oil industry continues to drill deeper to reach new wells, electronics are being required to operate at extreme pressures and temperatures. Coupled with substantial real-time data targets, the need for robust high speed electronics is quickly on the rise. This paper presents a high temperature wideband low noise amplifier (LNA) with zero temperature coefficient maximum available gain (ZTCMAG) biasing for a downhole communication system. The proposed LNA is designed and prototyped using 0.25μm GaN on SiC RF transistor technology, which is chosen due to the high junction temperature capability. Measurements show that the proposed LNA can operate reliably up to an ambient temperature of 230°C with a minimum noise figure (NF) of 2.0 dB, gain of 16.1 dB, and P1dB of 19.1 dBm from 230.5MHz — 285.5MHz. The maximum variation with temperature from 25°C to 230°C is 1.53dB for NF and 0.65dB for gain. / Master of Science

high temperature

extreme environment

low noise amplifier

GaN on SiC

downhole communications system