An integrated approach is taken, starting from upstream (on the watershed) and going downstream (towards the receiving waters in the natural environment). This module is divided into three parts: (i) water quality (ii) Waste Water Treatment using bioprocesses (iii) Water Treatment using Physical and Chemical means.
This module is organized around courses and tutored work. It includes applications concerning biogeochemical modeling of rivers and sizing of different unit processes in order to treat water.

A project helps to synthesize and link the different topics taught in this module in a more integrated way. These tutorials and project correspond roughly to 30% of the module (including 20 hours of personal work in addition to classical course sessions)

http://ense3.grenoble-inp.fr/en/academics/water-quality-and-treatment-5eus5qte-1 Understanding and modeling pollutions transfer processes on natural ponds & urbanized area
Understandind their impact on the natural and urban environment
Developing strategies in terms of planning and pollution control to limit these impacts
Ensuring the production of water suitable for various uses (domestic, industrial, …). Grenoble INP Institute of Engineering Univ. Grenoble Alpes Grenoble – Polygone scientifique Water Quality and Water Treatment module

– Understanding and modeling pollutions transfer processes on natural ponds & urbanized area
– Understandind their impact on the natural and urban environment
– Developing strategies in terms of planning and pollution control to limit these impacts
– Ensuring the production of water suitable for various uses (domestic, industrial, …). Bases on Transport Phenomena (Convection-Dispersion-Reaction Equation)(Cf S1, Advanced Fluid Mechanics module).
The module is largely self-consistent on the other points. However, certain items included in this module are discussed in: Hydrology for Engineers (S3) Hydraulics (S3), Geoenvironment (S4) Environmental systems (Hydrosystèmes) (S4) Philippe Sechet 5 2nd year of master Lecture Course content can evolve at any time before the start of the course. It is strongly recommended to discuss with the course contact about the detailed program.

Please consider the following deadlines for inbound mobility to Grenoble:
– April 1st, 2020 for Full Year (September to June) and Fall Semester (September to January) intake ;
– September 1st, 2020 for Spring Semester intake (February – June). 1 Exam (50% of the total mark) + 2 x Pratical Sessions (25%) + 1 Project (25%) international.cic_tsukuba@grenoble-inp.fr

Structured Digital Documents XML-DNS
Pre-media technologies
3D printing
Digital files for printing
Networks
Form web and IT project management

http://pagora.grenoble-inp.fr/en/international/fall-semester-paper-sciences-biorefinery-biomaterials-30-ects-1#page-programme Grenoble INP Institute of Engineering Univ. Grenoble Alpes Grenoble – Domaine universitaire – Saint-Martin-d’Hères Isabelle Desloges 8 1st year of master Lecture Course content can evolve at any time before the start of the course. It is strongly recommended to discuss with the course contact about the detailed program.

Please consider the following deadlines for inbound mobility to Grenoble:
– April 1st, 2020 for Full Year (September to June) and Fall Semester (September to January) intake ;
– September 1st, 2020 for Spring Semester intake (February – June). Final exam international.cic_tsukuba@grenoble-inp.fr

The course presents an overview of the problems of asset management that owners of numerous structures and networks are facing and that require engineering tools appropriate to the scale of analysis. The module thus covers methodological aspects (using concepts from the decision support) for the determination of the health status of a structure or a network that changes over time based on the objective analysis of the results of programmed inspection as well as more specific diagnosis surveillance. It also aims at presenting all the physical phenomena that explain the gradual deterioration of structures and reducing their safety or serviceability. Finally, using case studies in different areas (dams, dikes, networks, …) it provides the technological elements of the rehabilitation process.

http://ense3.grenoble-inp.fr/en/academics/asset-management-for-civil-engineering-works-and-networksetworks-hoe-master-he-5eus5gpo-1 Understanding of modeling tools used to describe the change over time of structures and their functioning
Developing strategies for monitoring, assessment and diagnosis of civil engineering structures and networks (water and wastewater networks, dams, dikes, tunnels and railways)
Knowledge of physical phenomena of degradation of materials and structures, knowledge of the main pathologies
Being able to choose among the main techniques for structures rehabilitation and to know the respective impact on their serviceability and safety. Grenoble INP Institute of Engineering Univ. Grenoble Alpes Grenoble – Polygone scientifique – Understanding of modeling tools used to describe the change over time of structures and their functioning
– Developing strategies for monitoring, assessment and diagnosis of civil engineering structures and networks (water and wastewater networks, dams, dikes, tunnels and railways)
– Knowledge of physical phenomena of degradation of materials and structures, knowledge of the main pathologies
– Being able to choose among the main techniques for structures rehabilitation and to know the respective impact on their serviceability and safety. notions of hydrology, hydraulics and civil engineering Frédéric Dufour 5 2nd year of master Lecture Course content can evolve at any time before the start of the course. It is strongly recommended to discuss with the course contact about the detailed program.

Please consider the following deadlines for inbound mobility to Grenoble:
– April 1st, 2020 for Full Year (September to June) and Fall Semester (September to January) intake ;
– September 1st, 2020 for Spring Semester intake (February – June). Continuous exam (2/3) + Final exam (1/3) international.cic_tsukuba@grenoble-inp.fr

Printed electronics (courses and labwork)
Printed electronics : components
Digital printing
Electronics basics

http://pagora.grenoble-inp.fr/en/international/fall-semester-paper-sciences-biorefinery-biomaterials-30-ects-1#page-programme Grenoble INP Institute of Engineering Univ. Grenoble Alpes Grenoble – Domaine universitaire – Saint-Martin-d’Hères Isabelle Desloges 5 1st year of master Lecture Course content can evolve at any time before the start of the course. It is strongly recommended to discuss with the course contact about the detailed program.

Please consider the following deadlines for inbound mobility to Grenoble:
– April 1st, 2020 for Full Year (September to June) and Fall Semester (September to January) intake ;
– September 1st, 2020 for Spring Semester intake (February – June). Final exam international.cic_tsukuba@grenoble-inp.fr

Architectures of RF wireless systems; ISM bands; The atmospheric channel; IEEE802.X.X regulations; Architectures of RF Front-End ; System Parameters; Link budget ; Standard Technologies; Cellular systems; Zigbee; Bluetooth; WiGiG; UWB; Software defined Radio; Cognitive Radio

http://esisar.grenoble-inp.fr/en/academics/wireless-rf-systems-5amsc534 Grenoble INP Institute of Engineering Univ. Grenoble Alpes Valence – Autres This lecture study wireless RF Systems. The main architectures are presented and compared. Standard technologies are presented. It concerns : ZIGBEE, BLUETOOTH, RFID, UWB, WIGIG. New technologies such as Software Defined Radio (SDR) Cognitive Radio are also presented. General Electronics
RF Electronics (matching)
Antennas (impedance, gain)
Signal Processing,
Digital signal
Modulation/Demodulation
Signal to Noise Ratio (SNR) / Bit Error Rate (BER) Smaïl TEDJINI 3 2nd year of master Lecture Course content can evolve at any time before the start of the course. It is strongly recommended to discuss with the course contact about the detailed program.

Please consider the following deadlines for inbound mobility to Grenoble:
– April 1st, 2020 for Full Year (September to June) and Fall Semester (September to January) intake ;
– September 1st, 2020 for Spring Semester intake (February – June). 1H45 ; Written exam ; Calculator and Documents are authorized
25%TP = 25% Homework (DM)+ 75%Exam international.cic_tsukuba@grenoble-inp.fr

Signal processing (problem based learning)
Sustainable development
Technical intelligence
Production management
Company visits

http://pagora.grenoble-inp.fr/en/international/fall-semester-paper-sciences-biorefinery-biomaterials-30-ects-1#page-programme Grenoble INP Institute of Engineering Univ. Grenoble Alpes Grenoble – Domaine universitaire – Saint-Martin-d’Hères Isabelle Desloges 6 1st year of master Lecture Course content can evolve at any time before the start of the course. It is strongly recommended to discuss with the course contact about the detailed program.

Please consider the following deadlines for inbound mobility to Grenoble:
– April 1st, 2020 for Full Year (September to June) and Fall Semester (September to January) intake ;
– September 1st, 2020 for Spring Semester intake (February – June). Final exam international.cic_tsukuba@grenoble-inp.fr

Introduction : System vs Embedded Systems; SOC design challenges, SOC modelling, Hardware Software partitionning.
System on programmable chip Architectures
SOPC design flow
Applications

http://esisar.grenoble-inp.fr/en/academics/advanced-processor-architecture-and-soc-design-5amce514 Grenoble INP Institute of Engineering Univ. Grenoble Alpes Valence – Autres To be able to choose and to exploit the more appropriate processor architecture for a given application.
To be familliar with SOC design techniques and challenges – Digital design (VHDL or Verilog; FPGA design)
– Embedded software Programming (C; Assembly Language)
– Processor Architecture (RISC Architecture, ARM processor) David HELY 3 2nd year of master Lecture Course content can evolve at any time before the start of the course. It is strongly recommended to discuss with the course contact about the detailed program.

Please consider the following deadlines for inbound mobility to Grenoble:
– April 1st, 2020 for Full Year (September to June) and Fall Semester (September to January) intake ;
– September 1st, 2020 for Spring Semester intake (February – June). Exam 1h30 + Labs international.cic_tsukuba@grenoble-inp.fr

Models for security analysis;
The need for cryptographic primitives and protocols;
Symmetric cryptosystems: design, make-up, analysis;
Other symmetric protocols and algorithms;
Arithmetic for asymmetric cryptography;
Examples of asymmetric cryptosystems;
Implementation of cryptographic primitives

Grenoble INP Institute of Engineering Univ. Grenoble Alpes Valence – Autres After the course, the student should be able to:
analyze the security needs of a communication and/or computation system at an algorithmic/informational level;
grasp the design principles of cryptographic primitives;
implement a cryptographic primitive in hardware knowing its specification. Hardware design courses: digital design, FPGA, VHDL or Verilog Yann KIEFFER 3 2nd year of master Lecture Course content can evolve at any time before the start of the course. It is strongly recommended to discuss with the course contact about the detailed program.

Please consider the following deadlines for inbound mobility to Grenoble:
– April 1st, 2020 for Full Year (September to June) and Fall Semester (September to January) intake ;
– September 1st, 2020 for Spring Semester intake (February – June). E1: result of end-term written exam (90 min);
E2: individual oral examination (30 min);
CC: semester-long assessment international.cic_tsukuba@grenoble-inp.fr

1. An optimization-based approach for control of complex systems (Optimization-based control; Generic prediction models; Generation of a reference trajectory/profile; Set-theoretic elements; Mixed-integer representations in control design)
2. Cooperative control of multi-agent dynamical systems (System description; collision avoidance formulation; Area coverage for multi-agent systems in multi-obstacle environment; A tight configuration of multi-agent formation; centralized MPC, Distributed MPC; decentralized MPC)
3. Stability analysis
4. Examples, simulations, benchmarks and applications (Flight control experiments of Unmanned Aerial Vehicles; Microgrid energy management; Decentralized supervision and control of water networks)

http://esisar.grenoble-inp.fr/en/academics/decentralized-control-of-complex-systems-5amac554 Grenoble INP Institute of Engineering Univ. Grenoble Alpes Valence – Autres The goal of this course is the optimal constrained control of complex dynamical systems. Elements from control theory and optimization will be merged together in order to provide useful tools which will be further applied to various problems involving multi-agent dynamical systems and interconnected systems in general. Beside classic control challenges related to the centralized vs distributed vs decentralized approaches, the stabilization and the tracking performances of each agent, there are a series of constraints imposed by the interaction with the environment and between themselves (anti-collision, avoidance constraints) as well as solving a collaborative task (e.g., maintain a fixed formation). This is generally the case with vehicles evolving in the same physical space, collaborative robots or drones covering a certain area. Some application benchmarks like control and coordination of multiple drones, energy management in complex energy systems and water distribution networks are discussed. Algorithms and programming, Linear and non-linear control, Optimal and predictive control Ionela PRODAN 2.5 2nd year of master Lecture Course content can evolve at any time before the start of the course. It is strongly recommended to discuss with the course contact about the detailed program.

Please consider the following deadlines for inbound mobility to Grenoble:
– April 1st, 2020 for Full Year (September to June) and Fall Semester (September to January) intake ;
– September 1st, 2020 for Spring Semester intake (February – June). E1 : Oral exam (in English) of 20 minutes for a team of students. E2 : Oral exam (in English) of 20 minutes and a report (in English). international.cic_tsukuba@grenoble-inp.fr

There ar only tree main approaches. The observer-based approach, the parity-space approach, and parameter identification-based methods. In order to optimize FDI indications, the following two step are developped :
The first step is to design a filter based on a model of the plant to generate a vector known as the residual. The residual should ideally be zero (or zero mean) under no-fault conditions.
The second step is to make decisions on whether a fault has occurred. This step is usually done using statistical tools to test if the residual has significantly deviated from zero.

http://esisar.grenoble-inp.fr/en/academics/model-based-fault-diagnosis-for-linear-systems-5amac514 Grenoble INP Institute of Engineering Univ. Grenoble Alpes Valence – Autres Fault detection and isolation (FDI) is a subfield of control engineering which involves monitoring a system, identifying when a fault has occurred, and pinpointing the type of fault and its location. Model-based techniques of fault detection and isolation use a model to investigate/analyze the occurrence of faults. The system model may be mathematical or knowledge-based. We focus our attention on mathematical models. State space representation
Observer design
Identification H2
Algebre of matrice : Rank, ker, eigenvalue … Damien KOENIG 3 2nd year of master Lecture Course content can evolve at any time before the start of the course. It is strongly recommended to discuss with the course contact about the detailed program.

Please consider the following deadlines for inbound mobility to Grenoble:
– April 1st, 2020 for Full Year (September to June) and Fall Semester (September to January) intake ;
– September 1st, 2020 for Spring Semester intake (February – June). Final exam session 1, calculators authorized + 1 handwritten sheet A4 R/V, duration 1h30. international.cic_tsukuba@grenoble-inp.fr

1 Verification and test of critical and secure digital systems: Introduction (Context and issues; Verification vs Test; DO-254 Standard); Hardware systems verification (Simulation; Emulation & Prototyping); Hardware Testing (Defects and faults modeling; Automatic Test Pattern Generation (ATPG); Design for Test and Bult-in-Self-Test (DfT, BIST); Digital board testing (boundary scan).
2 HW/SW Co-Verification & Co-Development: Microelectronic context and trends (SoC, MPSOC); SoC design flow (Hadware/Software Co-design approach; Plateform based design); Introduction to SystemC (Starting with SystemC; Communication channels; New abstraction level: Transaction Level Modeling); Co-verification of Harware and Software systems (Context and definitions; Co-verification approaches based on ISS, BFM, TLM and emulation, criteria to choose a verification approach)
3 Hardware Security: Introduction & cryptography basis; Hardware Vulnerabilities (Fault Attacks; Side Chanel Attacks; Integrated Circuit Trustworthiness (Countermeasures, Security Certification and Case studies) Smartcard; FPGA)
Laboratories:
– VHDL & PSL Simulation with QuestaSim (Mentor GraphiCs)
– Simulation vs “prototyping and integrated logical analyzer” ChipScopePro (Xilinx)
– SRAM embedded memory test on FPGA Spartan 3 card (Xilinx)
– On the use of communication channels (Fifo, Mutex, Semaphore) to model a communication architecture
– SoCLib – “Emulation of a Hardware/Software architecture used for image processing”

http://esisar.grenoble-inp.fr/en/academics/verification-and-test-of-secure-circuits-5amse515 Grenoble INP Institute of Engineering Univ. Grenoble Alpes Valence – Autres At the end of the lecture, the students will be able to verify, to test digital architectures and to analyse the vulnerabilities of embedded systemes. Then, they will be able to perform attacks and to design appropriate countermeasures. Neccessary: Hardware Description Language (HDL, verilog or VHDL) for simulation (testbench) and design, logical synthesis, FPGA, processor architecture (processor models, instruction set architecture), C programming
Ideally: bases of object oriented programming David HELY; Vincent BEROULLE 6 2nd year of master Lecture Course content can evolve at any time before the start of the course. It is strongly recommended to discuss with the course contact about the detailed program.

Please consider the following deadlines for inbound mobility to Grenoble:
– April 1st, 2020 for Full Year (September to June) and Fall Semester (September to January) intake ;
– September 1st, 2020 for Spring Semester intake (February – June). Terminal Exam, First session, written, 3h, only document allowed “syntaxe VHDL”, no calculator
Labs: average of laboratory exams international.cic_tsukuba@grenoble-inp.fr

Groups consist of at least 4 students following different specialties. Subjects (open and multidisciplinary) are offered by responsible of 5th year module. The job is done by each group independently; groups have access to the SACCO platform and TP classrooms of the school.

http://esisar.grenoble-inp.fr/en/academics/innovation-project-5ampx504 Grenoble INP Institute of Engineering Univ. Grenoble Alpes Valence – Autres Assess and enhance: Skills for the development of multidisciplinary systems; Work in a multidisciplinary team; The ability to innovate; Autonomy David HELY, Etienne PERRET, Vincent BEROULLE, Damien KOENIG 4 2nd year of master Seminar Course content can evolve at any time before the start of the course. It is strongly recommended to discuss with the course contact about the detailed program.

Please consider the following deadlines for inbound mobility to Grenoble:
– April 1st, 2020 for Full Year (September to June) and Fall Semester (September to January) intake ;
– September 1st, 2020 for Spring Semester intake (February – June). P1 = Mean of report evaluation and oral presentation international.cic_tsukuba@grenoble-inp.fr