PAGE CONTENTS
Objectives
The final objective of the project is to identify and to develop a simplified RF frequency converter line-up capable to be integrated in a single MMIC (SCFC) and, at the same time, to provide all the main functionalities included in the more complex conventional equipment, required to meet the radical changes that are involving the future satellites for telecommunications, in terms of architectures and costs, mainly for LEO and MEO constellations.
To hit this target, the Single Chip Frequency Converters have the following characteristics:
- Integrate the three main functionalities of a classical frequency converter line-up (LNA, Broadband Mixer and Power Amplifier) and increase of about 1 order of degree the integration density with respect to the today’s space qualified frequency converters, often based on very complex and expensive hybrid modules;
- Be compatible with different frequency schemes;
- Provide the gain adjustment facility;
- Provide the same performances of consolidated classical frequency converters.
Looking at the conversion schemes required by the main segments, two different MMICs are developed and tested:
- A Ka/Ka band Single Chip Frequency Converter
- A Ku/Ku band Single Chip Frequency Converter
Furthermore, the design of a full Down Converter line-up (DoCon) including the output filter for frequency plan customization is performed at both Ku and Ka bands and a Breadboard based on one chain DoCon is developed and tested.
Challenges
The main challenges addressed by the project are:
- The integration in a single 25mm2 MMIC, based on European technology, of all the functions actually used in the conventional converters’ RF chain: RF and IF gain amplifier, mixer core, LO buffer, RF power amplifier, variable gain and attenuation blocks.
- The implementation, within the same chip, of the advanced features required by the future applications: gain adjustment in the range of 20 dB, full compensation of the gain variation over temperature.
- The implementation of broadband conversion ranges, with quite high relative bandwidth for RF, LO and IF components.
- To integrate 4-channel Downconverter lin-up in a single hybrid block.
System Architecture
The optimum architecture for the SCFC MMIC is shown in the following figure. The different elementary blocks, and related gain and attenuations, have been properly distributed and positioned over the chain for the best trade-off between Gain, Linearity, LO harmonic rejection and Noise. Here below the main characteristics of the different functions highlighted in the picture:
- VGA1: RF Variable Gain Amplifier that provides the first stage of Gain and its continuous gain control is implemented to compensate the overall gain variation over temperature.
- DS1: RF 3-bit Digital Step Attenuator that performs the first steps of the SCFC gain attenuation from 0 dB to 7 dB, out of the total variation of 20 dB.
- DB Mixer: Broadband Mixer Core and LO Buffer to performs the frequency conversion according to the specific frequency synthesis.
- VGA2+DSA2: IF Gain stage and 2-bit Digital Step Attenuator, at the output of the Mixer, provide gain and perform the remaining 13 dB of gain variation.
- MPA: IF Medium Power Amplifier that provides the remaining gain step and the required linearity levels.
The architecture of the full Converter (DoCon), shown in figure below, is based on the SCFC cascaded after an isolator at the RF port and before the IF Filter and an output isolator.
Plan
The project is developed on the basis of the following tasks
- Task 1: Identification of best architectures, for SCFC and DoCon, and definition of the Baseline Specifications;
- Task 2: Critical Elements and single functionalities Design and Test
- Task 3: SCFC and RF Line-up Detailed Design
- Task 4: Manufacturing Integration & Test
and though the following Milestones:
- Preliminary Design Review
- Critical Design Review
- BreadBoard Test Review
- Detailed Design Review
- Final Review.
Current Status
Project has been completed. The SCFCs, both Ku- and Ka-band, and the breadboard for DoCon demonstrator have been manufactured and tested with results very close to the requirements.
