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The project objective is to demonstrate the feasibility of a wideband IQ-modulator based on SiGe HBT technology, which can be used in ground-segment equipment up to Ka-band. The project activities include the design, manufacturing, and testing of a SiGe MMIC satisfying functional and state of art performance requirements.
As essential part of a direct Modulator design this MIMC allows to extend to almost 5 octaves the frequency output band, compared to COTS components that almost cover only two octaves in a similar band of interest.
Nowadays no commercial part numbers are available to cover the ESA specified bandwidth from 1 GHz to up to at least 30 GHz with a wide modulation bandwidth (min. 500 MHz) and a high linearity. Direct conversion modulators in C band and in the lowest portion of Ka band (up to 23 GHz) are sold by manufacturers as separate parts, SIMO shall extend the bandwidth capability up to the whole Ka band, while at the same time include also L to C-band functionality.
SIMO allows a new generation of direct conversion transmitter from 1GHz up to 30 GHz thus extending TX functionality both to lower and higher frequencies. The input signal may either be baseband IQ DC coupled or IF IQ AC coupled for frequencies up to lower portion of L-band.
Additionally, SIMO targets low power consumption in the order of 0.5W.
An OIP3 of 20 dBm as well as a sideband suppression of 30 dB in typical conditions allows at the same time, good linearity. An additional internal and by-passable frequency doubler is foreseen to ease SIMO integration into high frequency PCBs, or hybrids with no need of complex waveguide MMIC external structures for the LO feeding in the Ka band.
SIMO is a wideband direct conversion IQ modulator.The functionality is obtained using two core mixer cells operating with a quadrature Local Oscillator signal and then summed-up. Each core cell is based on a differential Gilbert cell. The quadrature Local Oscillator signal generation section is based on a bank of four arms passive quadrature shifter so to cover, with overlapping bandwidth, the entire frequency working range. Each passive quadrature shifter is based on a 3 stage cascaded RC polyphase network. In order to limit phase and amplitude unbalances SIMO employs a well-balanced differential architecture as well as layout symmetry is adopted whenever possible. An internal programmable frequency doubler on LO chain allows the user with half frequency LO inputs.
The project plan is divided into 5 tasks:
Two milestones are foreseen: