The purpose of this consultation is the supply, delivery, commissioning and training in the implementation of equipment for the Institute of Electronics and Digital Technologies of Rennes (I.E.T.R.) and the National School of Applied Sciences and Technology of Lannion (ENSSAT). CPER-ERDF funding programme: The scientific equipment that is the subject of this contract is part of the "Cymocod - phases 1 and 3" project led by the University of Rennes and funded as part of the CPER 2021-2027 scheme integrating funding from the European Union (ERDF). The phases are divided as follows: Cymocod phase 1: concerns batch 2 "Frequency extenders"; Cymocod phase 3 Lannion: concerns lot 17 "Airborne hyperspectral sensor compatible with drone"; Cymocod phase 3 Rennes: applies to all other lots

The Nanorennes-IETR platform, within the framework of the Cymocod State-Region Plan (CPER) contract, must be equipped with a new evaporative thin-film deposition machine. The equipment will have to make deposits of thin but also relatively thick films (5?m) of mainly metallic materials on substrates with a maximum diameter of 100mm with 150mm as an option. The system will need to have an electron gun system to evaporate the materials to be deposited

This equipment is intended to create new measurement and exposure systems in order to strengthen the technological/metrology base of the Bioem platform of the M2ars platform. These include exposure systems above 6 Ghz based on high-power sources

The purpose of this lot is to supply an Rfsoc FPGA system with an expansion board. The system must be equipped with at least 8 inputs and 8 outputs, with Dacs (Digital-Analog Converters) with a minimum resolution of 14 bits and a sampling rate of at least 10 GSPS (Giga Samples Per Second) for signal generation, as well as Adcs (Analog-Digital Converters) of at least 14 bits and a sampling rate of at least 5 GSPS for signal acquisition. The operating frequency for each output shall cover the range of 300 MHz to 2.5 GHz. The maximum desired output power is 6dbm

The project is part of the realization of the CPER 2021-2026 "Cymocod" coordinated by the Institute of Electronics and Digital Technologies - IETR, UMR CNRS 6164.As part of our commitment in the field of bioelectronics, we seek to design, adapt and optimize complete systems covering the crucial aspects of exposure, dosimetry, characterization and bioelectronic microsystems. The main objective of this project is to meet the complex requirements of bioelectronic applications, where communication and interaction with biological tissues require advanced technological solutions

The project is part of the realization of the CPER 2021-2026 "Cymocod" coordinated by the Institute of Electronics and Digital Technologies - IETR, UMR CNRS 6164.As part of our commitment in the field of bioelectronics, we seek to design, adapt and optimize complete systems covering the crucial aspects of exposure, dosimetry, characterization and bioelectronic microsystems. The main objective of this project is to meet the complex requirements of bioelectronic applications, where communication and interaction with biological tissues require advanced technological solutions

The project is part of the realization of the CPER 2021-2026 "Cymocod" coordinated by the Institute of Electronics and Digital Technologies - IETR, UMR CNRS 6164.As part of our commitment in the field of bioelectronics, we seek to design, adapt and optimize complete systems covering the crucial aspects of exposure, dosimetry, characterization and bioelectronic microsystems. The main objective of this project is to meet the complex requirements of bioelectronic applications, where communication and interaction with biological tissues require advanced technological solutions

The objective is to develop a measurement system to characterize connected objects in terms of energy consumption and electromagnetic emanation. The system is based on the control of USRP-type software-defined radio modules allowing the acquisition and generation of ultra-wideband multichannel signals, as well as all the equipment necessary for the automated positioning of the object under test, the RF equipment in terms of probes and measurement cables and the very high speed control station (100 Gbit/S)

The demand for the spectral detection system (monochromator and spectrograph/detection with fittings) and its control system is part of research and innovation work covering electromagnetism and resonant optoelectronic devices and their applications in sensors and fine metrology for the dynamic monitoring of substances from the process industries. Indeed, the need to develop integrated instrumentation and its high-sensitivity detection optoelectronics is a major challenge for the fields and industries of biomedical (galenic pharmacology and associated colloidal products) and therefore health, agri-food (including Breton dairy cows), cosmetics and energy (battery electrolytes) for rapid tests and diagnostics to be carried out in 'On-line' and real-time analysis laboratories with little effort. Substances. All Industries

Since its advent in the mid-1980s, hyperspectral imaging has continued to evolve from a technical point of view (miniaturization of sensors, recording capacity, multiplicity of spectral bands and widening of spectral ranges). To meet the new needs raised by military, scientific and commercial applications (security, environmental and health control, medical, urban planning), it is now necessary to have a new observation system covering a wide spectral range that can be deployed on a light aircraft such as a drone. This type of carrier makes it possible to cover small areas with a lower cost and greater flexibility and responsiveness than an airborne vector such as an aircraft

Radar identification is a very sensitive area because the probability of confusion between targets remains high. It is therefore necessary to propose new diversities to the wave in order to provide additional information necessary to improve the probability of identification. The use of orbital angular momentum can be one of the answers to this challenge, especially for the study of targets with rotational symmetry. This input of information for identification can be carried out either in static, such as the determination of the number of branches to a cross or star, or in dynamics by determining the angular rotation speed of a plane object by measuring the rotational Doppler shift and studying the Doppler shift modulation provided by the shape of the object

The equipment included in this batch are frequency extenders. The microwave measurement chain is based on a vector network analyzer coupled with VDI Inc. frequency extenders. The objective is to evolve this system to add a measurement channel: either by adding a transmitter module including a reference signal to VDI Inc.'s Txref and Rx modules; or by replacing all the frequency extender modules, i.e. by offering two Txref type modules and one Rx type module

The equipment detailed below is defined in the context of the development of a radio-software test bench. Such a test bench requires a multi-channel signal generation system, and a multi-channel acquisition system. In order to comply with portability constraints, with a view to possible development in difficult environments, this equipment will be requested in PXI format. They will be able to be integrated into a PXI chassis, allowing the entire measurement system to be integrated into a single assembly. A controller card will be added to ensure fast data transfer and storage. All of this will require integration into a chassis. An 18-slot chassis is required to accommodate all PXI cards. Finally, a software-defined radio will be needed to begin the development and processing of new waveforms, for example

The equipment detailed below is defined in the context of the development of a radio-software test bench. Such a test bench requires a multi-channel signal generation system, and a multi-channel acquisition system. In order to comply with portability constraints, with a view to possible development in difficult environments, this equipment will be requested in PXI format. They will be able to be integrated into a PXI chassis, allowing the entire measurement system to be integrated into a single assembly. A controller card will be added to ensure fast data transfer and storage. All of this will require integration into a chassis. An 18-slot chassis is required to accommodate all PXI cards. Finally, a software-defined radio will be needed to begin the development and processing of new waveforms, for example

The equipment detailed below is defined in the context of the development of a radio-software test bench. Such a test bench requires a multi-channel signal generation system, and a multi-channel acquisition system. In order to comply with portability constraints, with a view to possible development in difficult environments, this equipment will be requested in PXI format. They will be able to be integrated into a PXI chassis, allowing the entire measurement system to be integrated into a single assembly. A controller card will be added to ensure fast data transfer and storage. All of this will require integration into a chassis. An 18-slot chassis is required to accommodate all PXI cards. Finally, a software-defined radio will be needed to begin the development and processing of new waveforms, for example

A PXI chassis equipped with 2 receiver modules and 2 resignation modules, complementing the existing chassis, the modules must be interchangeable between chassis to provide varied possibilities for the overall system. On the other hand, previously developed programs must be compatible with the new chassis

Such a test bench requires a multi-channel signal generation system, and a multi-channel acquisition system. In order to comply with portability constraints, with a view to possible development in difficult environments, this equipment will be requested in PXI format. They will be able to be integrated into a PXI chassis, allowing the entire measurement system to be integrated into a single assembly. A controller card will be added to ensure fast data transfer and storage. All of this will require integration into a chassis. An 18-slot chassis is required to accommodate all PXI cards. Finally, a software-defined radio will be needed to begin the development and processing of new waveforms, for example

This equipment is intended to create new measurement and exposure systems in order to strengthen the technological/metrology base of the Bioem platform of the M2ars platform. These include exposure systems above 6 Ghz based on high-power sources

This equipment is intended to create new measurement and exposure systems in order to strengthen the technological/metrology base of the Bioem platform of the M2ars platform. These include exposure systems above 6 Ghz based on high-power sources