I have recently made available a new version on the A600 amplifier based on MRF300 LDMOS transistors. Here is the list of changes and improvements that come with v2.0.
1. Redesigned and improved PCB
All components are now on the top side, while the bottom side is a continuous ground plane in direct contact with the heatsink. This improves the electrical ground even further and (together with the black coating) maximises thermal performance. It also allows for the thermal sensor and the temperature-compensating bias thermistor to be mounted as SMD parts directly on the PCB and not require additional heatsink mounting holes.
2. 70MHz band coverage
Thanks to slightly better layout of the input traces and the use of semi-rigid transmission line instead of coaxial in the output RF power transformers, the coverage has been extended to 1.8 to 72Mhz. A 4.7pF PCB capacitor at the input of the directional coupler improves performance & matching on 6m and especially 4m. Keep in mind in most countries 450W is way above the legal limit on the 4m band (!).
3. Easy-to-use bias circuit
The bias circuit now uses the same 5V (5.36V more precisely) voltage regulator circuit that supplies power to the thermal sensor and the current sensor. There are only two trimmers that adjust the bias voltage from 2.2V to 3V for each transistor and they come pre-set to a safe value. Now you don’t need to pre-adjust the bias before installing the transistors and you cant destroy the transistors by accidentally setting the bias too high.
4. New RF drive sensor and expanded Sensor Port
New onboard circuitry measures the drive power and provides a proportional continuous voltage at the Sensor Port within the 0-5V range. This can also be used as a RF drive detector for a (separate) automated RX/TX switching (RF vox) circuit. The Sensor Port has been expanded from 7 to 12 pins now and also provides a +5V 200mA supply voltage than can be used to directly power measurement & protection circuitry connected to the Sensor Port.
5. Can be set up for high drive (up to 100W)
The PCB now has a slot for installing a high-power RF attenuator on the same heatsink so the amplifier can be driven directly even with 100W transmitters. ATC FA10975P03DBFBK or the cheap RFP1398 are good examples of 100W 20dB attenuators that would have to be installed for this purpose. Otherwise, a straight jumper is fine.
6. More accurate current measurement
The current sensor has been replaced with ACS713ELCTR-30A-T, which is unidirectional but offers twice the output voltage per A compared to the previous ACS712. This will allow more accurate current measurement when using modest resolution ADCs (like the 10-bit on some Arduinos).
7. Onboard jumper for testing without a LPF
The module is now supplied with an onboard jumper (R37) that shorts the LPF ports. This will allow you to run the initial testing without having a Low Pass Filters board connected. Once you get things going, R37 will have to be removed and a LPF board connected to the J2 & J3 ports.