Deliverable Final Management Report

PowerSWIPE (Project no. 318529) POWER SoC With Integrated PassivEs Deliverable 6.1.4 Final Management Report Dissemination level: PU Responsible Beneficiary Tyndall Due Date 31 st March 2016 Submission Date 30 th April 2016

Summary No and name D6.1.4 Final Management Report 1 Status Released Due Month 42 Date 31-March-2016 Author(s) Nicolás Cordero Editor Cian Ó Mathúna DoW Report on Project Management from October 2012 to March 2016 Dissemination Level PU - Public Nature Report Document history V Date Author Description Draft 18-Apr-2016 N.C. Draft 1.0 25-Apr-2016 N.C. et al. Inputs from all partners for WP reports 2.0 29-Apr-2016 N.C. Incl. effort vs WP and explanation use of resources 2.1 15-May-2016 N.C. et al. Feedback from Final Review 1 Disclaimer - The information in this document is provided as is and no guarantee or warranty is given that the information is fit for any particular purpose. The user thereof uses the information at its sole risk and liability. 2/51

1. Table of Contents 1. Table of Contents... 3 2. PROJECT PERIODIC REPORT... 4 3. Declaration by the scientific representative of the project coordinator... 5 3.1 Publishable Summary... 6 3.1.1 Description of project context and objectives... 6 3.1.2 Description of work performed and main results... 7 3.1.3 Final results and their potential impact and use (incl. socio-economic impact and the wider societal implications of the project)... 10 3.1.4 Project website, logos and partners... 12 3.2 Core of the report for the period: Project objectives, work progress and achievements, project management... 13 3.2.1 Project objectives for the period... 13 3.2.2 Work progress and achievements during the period... 13 3.2.3 Project management during the period... 40 3.3 Deliverables and milestones tables... 45 3.4 Explanation of the use of resources... 49 3.4.1 Planned versus actual use of resources. Adjustments... 49 3/51

2. PROJECT PERIODIC REPORT Grant Agreement number: 318529 Project acronym: POWERSWIPE Project title: Power System-on-Chip (SoC) with Integrated Passives Funding Scheme: FP7-ICT-2011-8 Date of latest version of Annex I against which the assessment will be made: 7 th September 2015 Periodic report: 1 st 2 nd 3 rd Period covered: from 1 st October 2012 to 31 st March 2016 Name, title and organisation of the scientific representative of the project's coordinator 2 : Prof. Cian O Mathuna, Senior Research Scientist, Tyndall National Institute, University College Cork Tel: +353-21-234 6350 Fax: n/a E-mail: cian.omathuna@tyndall.ie Project website 3 address: www.powerswipe.eu 2 Usually the contact person of the coordinator as specified in Art. 8.1. of the Grant Agreement. 3 The home page of the website should contain the generic European flag and the FP7 logo which are available in electronic format at the Europa website (logo of the European flag: http://europa.eu/abc/symbols/emblem/index_en.htm logo of the 7th FP: http://ec.europa.eu/research/fp7/index_en.cfm?pg=logos). The area of activity of the project should also be mentioned. 4/51

3. Declaration by the scientific representative of the project coordinator I, as scientific representative of the coordinator of this project and in line with the obligations as stated in Article II.2.3 of the Grant Agreement declare that: The attached periodic report represents an accurate description of the work carried out in this project for this reporting period; The project (tick as appropriate) 4 : has fully achieved its objectives and technical goals for the period; has achieved most of its objectives and technical goals for the period with relatively minor deviations. has failed to achieve critical objectives and/or is not at all on schedule. The public website, if applicable is up to date is not up to date To my best knowledge, the financial statements which are being submitted as part of this report are in line with the actual work carried out and are consistent with the report on the resources used for the project (section 3.4) and if applicable with the certificate on financial statement. All beneficiaries, in particular non-profit public bodies, secondary and higher education establishments, research organisations and SMEs, have declared to have verified their legal status. Any changes have been reported under section 3.2.3 (Project Management) in accordance with Article II.3.f of the Grant Agreement. Name of scientific representative of the Coordinator:... Date:.../.../... For most of the projects, the signature of this declaration could be done directly via the IT reporting tool through an adapted IT mechanism and in that case, no signed paper form needs to be sent 4 If either of these boxes below is ticked, the report should reflect these and any remedial actions taken. 5/51

3.1 Publishable Summary 3.1.1 Description of project context and objectives Combining high efficiency with cost-effective but high level of integration is the major driver in power electronics today. Significant R&D and product development activity is being carried out to develop power supplies that can be integrated directly with the actual semiconductor devices. These new miniaturised product formats are known as Power Supply on Chip (PowerSoC), which provide high integration in a small footprint for maximum power density, lowest component count and highest reliability. PowerSwipe responded to the call for advanced More-than-Moore elements and their integration and interfacing with existing technology by aiming to develop innovative Power Supply in Package (PwrSiP) and Power Supply on Chip(PwrSoC) technology platforms through highly integrated passives and advanced CMOS. The PowerSwipe concept addresses the key challenges of "systemability", "integratability" and "manufacturability" for System on Chip (SoC) power management platforms. An advanced design optimisation tool was developed with both component and system perspective. PowerSwipe has leveraged the existing expertise of the consortium in the areas of integrated passives and power management design to achieve a first integrated system-level design tool for SoC applications. Additionally, high-volume MEMS manufacturing processes for the monolithic power passives have been developed to enable deployment of the technologies in commercial applications. A custom PwrSiP/PwrSoC was developed to maximise the system performance in high volume silicon technology. On-chip intelligence will enable system performance to be optimised for different applications. A top-down system design approach takes full advantage of the benefits of the integrated magnetic and capacitive components while resolving issues due to smaller absolute component values, higher switching losses and increased on-chip interference and coupling. PowerSwipe targets the challenges of system design, engineering, technology and manufacturability of integrated power management systems. Two demonstrators (one high-voltage plus low-voltage at 10 MHz and the second one at 100 MHz) were designed and fabricated to address target applications (e.g. automotive) and system requirements (efficiency, performance, reliability/lifetime, cost and size). The PowerSwipe main objective is to establish Europe as the leading global player over the coming decade in this emerging space by creating a competitive, European supply chain in Power Supply platform for System on Chip applications with no major missing links. 6/51

Efficiency (%) Frequency (MHz) D6.1.4, Final Management Report, March 2016 3.1.2 Description of work performed and main results Description Europe is a world leader in innovative automotive systems with competencies covering the full supply chain from the main OEMs (Audi, BMW, Daimler, Fiat, PSA, RSA, VW) to Tier1 suppliers (Bosch, Continental, Magneti Marelli) to leading semiconductor companies (Infineon, ST). Today s cars contain up to 70 electronic control units, using multi-core μcontrollers. The vision for automotive control units in 2020 will be that multi-core μcontrollers will be directly connected to different battery voltages (12-48V). Because of the different voltage domains, multiple power supplies are needed for each μcontroller. These will be power supplies on-chip (i.e. PowerSoC) using granular power management system architecture. PowerSwipe has addressed a key roadblock for PowerSoC by, for the first time, miniaturising and integrating state-of-the-art, high density trench capacitor substrate technology with novel thin film magnetics on silicon to deliver a multi-component LC (inductor-capacitor) interposer which is then combined, in a 3D heterogeneous stack, with the μcontroller chip. To achieve this miniaturisation of the power passives, the switching frequency of the switched mode DC/DC converter needs to be increased from the traditional 1 to 5 MHz space (with 90%+ converter efficiency) into the 10MHz to 100MHz+ range. Results A Power Management IC has been designed in 40 nm CMOS technology. This PMIC is mounted onto a capacitive interposer, with an inductor on the side. The assembly is 3 3mm. Two different IC were assembled for comparison purpose as an innovative power stage structure (3-MOSFETs cascode) has been selected to enhance converter efficiency at 100MHz. The 3D assembly has been mounted onto a PCB and tested. Measured efficiency at 100 MHz has been compared against state of the art (SotA) converters. The innovative structure shows much better results than the classical approach. It allows having efficiency comparable with that for 10 MHz converters. 95 500 90 85 80 75 70 65 State of the art 60 100 MHz cascode 100 MHz standard 55 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 V OUT /V IN 200 100 40 20 10 Efficiency of 100MHz novel DC-DC converter vs. State of the Art 7/51

Tasks, Milestones and Deliverables Tasks performed since the beginning of the project 6-month Extension: Back-up run of integration/fabrication of Demo1 Functional testing of Demo1 Forensic testing of failed Demo1 samples Functional testing of ITV2 Exploitation plan Year 3: Finalise fabrication of passives (inductor, capacitor and interposer) Integration/fabrication of Demo1 Integration/fabrication of ITV2/Demo2 Functional testing of Demo1 Forensic testing of failed Demo1 samples Functional testing of ITV2 Demo1 validation plan Draft exploitation plan Year 2: Finalise all the IC designs: LV, HV and HF DCDC Tapeout and fabrication of ICs Analysis and optimisation of chosen architectures and selected blocks Improvement of models Passives (inductor, capacitor and interposer) fabrication Year 1: Inductor technology transfer Maintenance of project Web site. Dissemination activities (seminars, presentations, publications) Definition of target application requirements System architecture, block-level optimisation and integrated circuit design System level analysis and optimisation Analysis and optimisation of integrated passives Passives (inductor, capacitor and interposer) process development Inductor technology transfer Development of project Web site Achieved milestones Year3: Ms4.3 PSiP with integrated LC substrate (Demo2) (Month 35) Ms1.4 System architecture analysis completed (Month 32) Ms4.1 Intermediate test vehicle with integrated capacitors and inductors (ITV2) (Month 31) Ms4.2 PSiP with functional interposer with TSvs, capacitors and inductors (Demo1) (Month 30) Ms3.2 Inductor process transfer completed (Month 28) Ms3.3 Interposers ready for demos (Month 26) Year2: Ms3.1 Passive components ready (Month 23) 8/51

Ms1.3 Tape-out first prototype chips. Error-free GDSII layout in time (Month 21) Ms2.3 Detailed analysis and optimisation of individual blocks for the selected architectures (Month 18) Year1: Ms2.1 Architecture analysis and evaluation (Month 12) Ms2.2 Analysis and optimisation of integrated passives (Month 12) Ms1.2 First system architecture (Month 9) Ms1.1 Application requirements defined (Month 3) Completed and submitted deliverables 6-month Extension: D1.4 Optimised system architecture description (Month 42) D1.5 Optimised block-level specification (Month 42) D2.6 Analysis and Optimisation of Integrated Passives (Month 41) D2.7 Multi-disciplinary Platform for PwrSoC Design (Month 41) D4.3 Demonstrators Analysis and Characterisation (Month 41) D4.1.2 HW Demonstrator 1 Back-up Run (Month 39) D4.4.2 Forensic Testing for Back-up Run (Month 42) Additional Deliverable D5.2.2 Final Dissemination Report (Month 42) D5.3 Technology Implementation and Exploitation Plan (Month 42) D6.1.4 Final Management Report (Month 42) Year 3: D4.4 Forensic Testing (Month 36) D4.2 HW Demonstrator 2 (Month 35) D3.5 Report on interposer test (Month 34) D3.6 Report on process development for inductors (new process) (M34) D3.7 Report on process development on HV capacitors (M34) D4.1 HW Demonstrator 1 (Month 31) D3.3 Report on inductor technology transfer (Month 28) D3.4 Interposers fabricated for demos (Month 28) D5.3 Draft Exploitation Plan (Month 26) Year 2: D2.4 Architecture optimisation of 1 st prototype chips (Month 24) D2.5 Analysis and optimisation with improved models (Month 24) D3.2 Passive components fabricated (Month 23) D1.3 Design report of first prototype chips (Month 21) D2.3 Analysis and optimisation of selected architecture (Month 18) D5.2.1 Mid-term dissemination report (Month 18) Year 1: D1.1 First system architecture description (Month 12) D1.2 Target block-level specification (Month 12) D2.1 Analysis and evaluation of first system architecture (Month 12) D2.2 Analysis and optimisation of integrated passives (Month 12) D3.1 Inductor process documentation ready for transfer (Month 6) D5.1 Project Web site (Month 3) 9/51

3.1.3 Final results and their potential impact and use (incl. socio-economic impact and the wider societal implications of the project) PowerSwipe has developed...... a demonstrator, consisting of multi-component LC (inductor-capacitor) interposer, which can be combined in a 3D heterogeneous stack together with the SoC/PMIC chip... integrated passive components fulfilling the stringent temperature (125 C) and quality requirements required by the automotive market and thus closing today s gap in availability of components... inductor and capacitor based very high-frequency DC-DC converters in 40nm CMOS operating at 5V supply, ready for 3D integration with power passives... integrated very high-frequency DC-DC converters allowing PCB footprint reduction by ~100mm² per module, without compromising converter efficiency at 90%... missing system and component level optimisation tools to achieve optimum system configuration and efficiency for different operating modes... a demonstrator system targeted for Automotive Microcontroller, with optimized complete chain from car battery (5...48V) down to the core voltage domain (1V) System level schematic of the PowerSwipe project innovations 10/51

Achievements by partner IPDiA IFAT IFX/IPDiA Bosch CEI-UPM Lab Ampere Tyndall Breakthrough: Low-loss, high-density, trench power capacitors Established high volume, product line for new customers/applications High efficiency for high-voltage DCDC conversion demonstrated (88% at 10MHz for a 12V/5V conversion, exceeding state-of-the-art) Understanding integration of IPDiA capacitor/interposer with IFX ewlb artificial moulded wafer created for flip-chip bumping of limited number of chips coming from MPW Follow-on projects and collaboration with IFX and IPDiA 1 st CAD tool for PwrSoC High efficiency, 100-200MHz on commercial PwrSiP platform Highest efficiency thin film coupled inductor Technology transfer of magnetics on silicon to IFX 11/51

3.1.4 Project website, logos and partners Project Website: www.powerswipe.eu Project logo: Project banner: Project partners Participant organisation name Short name Country Tyndall National Institute, University College Cork Tyndall-UCC IRL Infineon Technologies AG, Regensburg IFX D Infineon Technologies Austria AG - Villach IFAT A IPDiA, Caen IPDiA F Centro de Electrónica Industrial, Univ. Politécnica de Madrid CEI-UPM E Robert Bosch GmbH, Stuttgart Bosch D Université de Lyon, Claude Bernard Lab Ampere F 12/51

3.2 Core of the report for the period: Project objectives, work progress and achievements, project management 3.2.1 Project objectives for the period The main objectives of the PowerSwipe project for year 3 and the 6-month extension (Month 25 to Month 42) were: Finalise fabrication of passives (inductor, capacitor and interposer) Integration/fabrication of Demo1 Integration/fabrication of ITV2/Demo2 Functional testing of Demo1 Functional testing of ITV2 Validation of Demo1 samples Draft exploitation plan The following figure shows the Gantt chart with the tasks, deliverables and milestones for the reporting period and to the end of the project (According to latest version of DoW, Sep 2015). 3.2.2 Work progress and achievements during the period WP1 System Specifications and Design WP Objectives for Year 3 Project extension Phase Characterization of 2 nd run of Demo1 system Finish all open deliverables 13/51

Work Progress Characterization of HV DCDC: finished successfully. Characterization of Demo1: not successful due to package interface issues. As consequence the following planned milestones and deliverables are limited: o MS14: System architecture analysis completed o Deliverable D1.4 Optimized system architecture description o Deliverable D1.5 Optimized block-level specification Achievements / Summary A complete, fully integrated power management system targeted for Automotive applications was developed. Based on the requirement definition the optimum system architecture was chosen, and the chip design was carried out, bringing 2 different chips into fabrication: a) HV DCDC chip (HV high voltage)) in 130nm BCD CMOS, to convert the car battery levels down to 3-5V, and b) Demo1 chip (LV low voltage) in 40nm CMOS. Final measurements were carried out on the HV DCDC chip. Two different setups were tested successfully, one operating the DCDC open loop, yielding up to 90% efficiency at 10MHz switching, and a second one with optimized mixed-signal controller (V 2 I C /V 2 I L control). However on Demo1, no meaningful electrical measurements were possible, even after having 2 different package manufacturing runs. Since the root causes are most probably packaging/metallisation issues, the detailed failure analysis is done in WP4. These investigations were closely connected to technology developments in WP3. HV DCDC Chip The HV DC-DC converter is an inductor-based step-down regulator that operates at a frequency of 10MHz. At the moment only the power stage has been implemented on silicon. The acceptable input voltage range goes from 6V to 16V while the output voltages for which the design has been optimized are 3.3V and 5V. The maximum output current is 500mA. Figure shows the block diagram of the implemented design. The power stage itself consists of a low-side switch and a high-side switch which are both 20V NMOS devices. 14/51

Figure 1.1. Block diagram of implemented design Characterization For test purposes a small board was created, which contains a HV DC-DC silicon die, directly bonded to the PCB with external inductor L=1µH (Coilcraft) and external capacitors Cout=470nF, Cls=47nF (Taiyo Yuden) Cin=220nF, Chs=22nF (Murata). Efficiency measurement yields close to 90% at 10MHz switching frequency and quite nice matching with simulated values, especially at higher loads. Additionally we tested the possibility to operate at even higher switching frequencies. The converter had shown a stable operation at frequencies up to 40 MHz with the same external components without adjust for higher switching frequencies. Also we built a prototype of mixed signal V 2 I C /V 2 I L controller, which was successfully tested together with HV DC-DC. This controller could be integrated in next silicon of HV DC-DC. 15/51

Figure 1.2. PCB with directly bonded HV DC-DC and external passives 1 0.9 0.8 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0 10 50 100 200 400 500 ILOAD [ma] Efficiency (40MHz) - Vout=5V Efficiency (10MHz) - Vout=5V Figure 1.3. Efficiency measurement. Fsw=10/40MHz Vin=12; Vout=5V Demo1a fully integrated power management chip The implemented Demo1a test chip is a complete, fully integrated power management chip for supplying automotive microcontrollers. The chip contains an integrated inductor based DC-DC buck converter and an integrated switched capacitor DC-DC converter. Beside the converters additional auxiliary circuits are placed: linear voltage regulators, different oscillators, bandgap references, current references, ADCs, temperature sensors, startup circuits. Furthermore, an artificial load is placed on the chip in order to emulate steep current jumps from a microcontroller load. The current ramps of the load are programmable and can be controlled by external control signals. 16/51

HV-Chip: 130nm BCD CMOS LV-Chip: 40nm (Flash) CMOS Figure 1.4. Block diagram of the fully integrated power management chip Demo1a Passive components Figure 1.5. Chip Layout of Demo1a The capacitors and inductors used for the circuits are implemented on the interposer that is placed between the chip and the package. C IN = 665nF, C OUT_LV = 400nF, C OUT_SC = 260nF, C fly = 30nF, L LV = 250nH. Implemented Switched Mode Power Supplies Two different types of power converter were developed during this project. The first one is a Switched Capacitor DC-DC converter (SC DC-DC) and the second one is an inductor based DC-DC converter (LC DC-DC). 17/51

Measurement Results Demo 1 Demo 1 could not be characterized as planned due to manufacturing issues. For details please see WP4 report. Therefore the project team decided to do a 2 nd run, based on the remaining silicon dies, both the 40nm CMOS IC provided by IFAT, and the passive silicon interposer, provided by IPDiA. This 2 nd run did not show the expected improvement in connectivity between the package balls and the interposer/ic. So again no meaningful electrical characterization of the 40nm chip was possible with the Demo1 samples. Figure 1.6. Demo1a Interposer/Package Interconnects and Signal Names 18/51

Impedance measurements Connectivity measurements Interposer CMOS Passives Sample Vdd_5v0 Vout_sc_ Vdd_pwr _evr dcdc Number [Cs,RS] [Cs,RS] [Cs,RS] no inductor x x no inductor x x x x Vout_lc_ dcdc [Cs,RS] Dum 1 to Dum 2 Dum 1 or 2 to Dum 3 Figure 1.7. Demo1A Interconnect Measurement Results NOTE: Dum1 to Dum2: Interconnect involves package only (ball-metal-ball) OK Dum1 to Dum3: Interconnect involves package and interposer/tsvs (ball-metal-tsv-metal-tsv-metalball) NOT OK Dum 4 to Dum 5 Dum 4 to Dum 6 Dum 5 to Dum 6 Dum 7 to Dum 8 Dum 4 or 5 or 6 to Dum 7 or 8 inside 1 open open open open 800mOhm open 800mOhm 800mOhm 800mOhm 800mOhm open inside 2 open open open open 700mOhm open 800mOhm 800mOhm 700mOhm 800mOhm open no inductor inside 3 750nF open open open 900mOhm open 800mOhm 900mOhm 800mOhm 900mOhm open 19/51

Inductance (nh) @ 10 MHz D6.1.4, Final Management Report, March 2016 WP2 Computer-aided Optimisation and Analysis Work Package Objectives The objective for the third year of WP2 can be summarized as follows: 2.1 Passive Components Improvement Validation The models developed for integrated inductors (both individual and coupled) have been improved accounting for second order effects not considered in the previous models. These second order effects have been obtained through the characterization of the first set of samples. Integrated power inductors have been measured and characterized and their main electrical parameters have been extracted under different operating conditions. Variation of the inductance with the bias current. As it is shown in Figure, the inductance is modified as the bias current is increased. This effect has been analyzed from the converter point of view by means of accurate simulations and it has been shown that its effect is negligible. New Models for Coupled Inductors. New analytical models for the coupled inductor structures shown in Figure used in the High Frequency converter (100MHz- 200Mhz) have been developed for the optimization. Validation of coupled inductor structures. Different coupled inductor structures have been analyzed and validated by measurements. The main design parameters for the coupled inductors are shown in Table and their layouts are shown in Figure. 500 50 0 250 500 750 1000 Bias Current (ma) Figure 2.1. Inductance as a function of the bias current (220nH inductor sample) Option A L Tx L Option B Figure 2.2. Alternative Coupled inductor structures considered for the HF DC-DC Converter 20/51

PowerSWIP E ITVs Table 2.1. Main Geometric and Electric Parameters of Integrated Coupled Inductor Samples L (nh) Core Core Copper Copper DCR Thicknes Length width Thickness (Ohm) s Device Footprint ITV 2A 33nH 1.2 µm 1.22 mm 72.2 μm 35 μm 0.084 2 mm 2 ITV 2B ITV 2C 47 nh Coupled (k=0.4) 1.6 µm 1.78 mm 50.62 15 μm 0.3425 2 mm 2 35 nh 1.6 µm 1.83 mm 75.71 μm 15 μm 0.155 2 mm 2 Coupled k=0.8 20 nh 1.6 µm 0.78 mm 97 μm 35 μm 0.053 2 mm 2 33nH 95,5 % 90.25% ITV 2A 85.6% ITV2B 90.25% 94.8% ITV 2C Figure 2.3. Layout of Integrated Coupled Inductor Samples 2.2 System Level Design and Optimization The main improvements regarding the System Level Design and Optimization Tool have been focused on: 21/51

Implementation of the improved models for the integrated magnetic components and the addition of multi-phase coupled converters with accurate models of the coupled inductors. These results have been validated with the High Frequency DC-DC converter and the main results are summarized in Table. It can be seen that even the highest efficiency is obtained with a single phase buck converter design operating at 200MHz. The reason is that the penalty on the efficiency of the semiconductors (3%) is compensated with the improvement on the efficiency of the magnetic component (95%). Table 2.2. Efficiency estimation for different couple inductor configurations for HF DC-DC Converter Inductor design Freq. (MHz) L (nh) Coupling factor Efficiency (magnetics) Efficiency (IC) Total efficiency ITV2a Single phase 200 33 -- 95,50% 87,40% 83% ITV2b Coupled 100 45 ~0.4 90% 90,40% 81% ITV2c Coupled +Lout 100 35+21 >0.8 85.6% 90,40% 77% The nonlinear effect of the variation of the inductance with the output current has also been validated at system level and it has been shown that even though there is a drop of the inductance of from 220nH with a bias current of 0A to 170nH at with a bias current of 500mA (see Figure ) the effect on the time domain is very small (with ideal inductor of 220nH the peak to peak current is I pp = 450mA and with the nonlinear inductor the value is I pp = 440mA) Figure 3.3. Comparison of the inductor current waveform for the 10MHz buck converter with ideal and nonlinear inductor (Red- non-linear Inductor, Blue- Ideal Inductor) Work Progress Regarding WP2 most of the objectives have been met. There are some tasks pending that have been delayed due to the problems encountered with the measurements of the samples: Coupled inductor models have been developed and validated. Analytical Models for Two different coupled inductor structures have been developed and validated by means of Finite Elements and Measurement. The system level optimization tool has been improved with more accurate models of the single inductors and coupled inductors. Additional fast ripple based controllers have been added to the optimization tool that allows improving the dynamic response and reduce the output capacitance to be integrated. Deliverables The deliverables of WP2 have been moved to M41 since they depend on the measurements to be performed to the samples, and were the cause of the extension of the project. 22/51

D2.6 Analysis and optimisation of integrated passives has been moved to M41 D2.7 Multi-disciplinary platform for PwrSoC design has been moved to M41 23/51

WP3 Technology Development Work Package Objectives and Significant Results 1) Inductor fabrication for Demo 1, ITV2 and Demo2 Fabricate inductors for Demo1, ITV2 and Demo2 and carry out reliability and testing of the fabricated inductors. Complete initial characterisation of inductors for Demo1, ITV2 and Demo2 and die-level reliability testing for same. Further optimise the lamination process for improving performance of inductors Complete the detailed reliability plan for inductors 2) Technology transfer and scale up (Tyndall to IFX) Set up a magnetics processing line in Regensburg, Germany based on Tyndall s processing of racetrack structures Develop optimised process for realising an air-core design on a 200 mm wafer Demonstrate fully fabricated device with closed magnetic core 3) Capacitor fabrication & interposer development Develop and demonstrate high voltage (BV=30V) process for HV stage Execute preliminary reliability study and extrapolate lifetime under Bosch specified usage conditions Implement PICS capacitors and interposer technologies for demonstrators Fabricate Demo1 (LV and HV) and ITV2/Demo2 interposers Process PICS wafers Develop and execute electrical testing and HF characterisation Assembly and evaluation of ITV2/Demo2 devices The back-up batch of Demo1 devices was integrated (see WP4) using backup interposer and inductor samples already fabricated during Year 3. WP3 has met all these objectives. Significant results from WP3 are listed below. Detailed description of all tasks in WP3 1) Inductor fabrication for Demo1, ITV2 and Demo2 Tyndall completed fabrication of Single Layer Metal (SLM) inductor designs for Demo1, ITV2 and Demo2 and for inductor reliability testing programme. Double Layer Metal (DLM) devices were completed by end of November 2014. Figure 3.1 below, shows image of a fully fabricated coupled inductor for Demo2 devices. All devices were tested at die-level at Tyndall before being shipped. 24/51

Figure 3.1. Demo2 coupled inductors Coupled Self-inductance Self-inductance Self-inductance Inductor design value per phase test value phase 1 test value phase 2 Demo2 45 nh 45.9 nh @ 10 MHz 44.8 nh @ 10 MHz The high frequency testing was carried out at Lab Ampere. Figure 3.2 shows the measured AC resistance and inductance as a function of frequency up to 100 MHz. Figure 3.2. Inductance, AC Resistance vs Frequency measurements done by Ampere Lab Additionally, Tyndall has developed a lamination process using sputter deposition of NiFe (permalloy) core. Figure 3.3 below shows the cross-section of a laminated NiFe core. The initial characterisation of the laminated core shows that this structure has a higher operational frequency (6 lamination of 100 nm thick-500 MHz) compared to a single lamination core (100 MHz) due to reduced eddy currents. Figure 3.3. Cross-section of a laminated core structure. 25/51

2) Magnetics processing technology transfer from Tyndall-IFX IFX and Tyndall worked together in establishing a magnetics processing line in Regensburg. Figure 3.4 shows some inductors fabricated at IFX (NiFe core is sputtered, 200nm thick std. permalloy target). Figure 3.4. Inductors fabricated at IFX The following processes were carried out. The resulting wafers and parts were sent to Tyndall for characterisation: Electro Chemical Plating of NiFe on dummy wafers Pattern Plating has been tested on Cu Seed Seed Etch has been demonstrated successfully (equals plating of first NiFe bottom core) NiFe plating on high topology has also been demonstrated (equals plating of the second NiFe core). The Magnetics on Silicon process from Tyndall has been successfully transferred and scaled up to 8 technology at IFX. 3) Development of new capacitor design method for low ESR Reduction of capacitance parasitic is a key challenge for performance of DCDC converters. For input capacitors, excessive resistance will result into slower response to load step. For the output capacitor, an excessive ESR would result in higher ripple / lower efficiency and an excessive ESL would limit the frequency of operation. Historically, most of the silicon integrated capacitor technologies show intrinsic limitation in term of ESR. This is mainly caused by the 3D structure/nature of refractory materials that are employed to build the capacitive structure within the 3D structures. IPDIA PICS technology naturally has such limitation. To address this limitation, IPDIA has been developing within PowerSwipe a new approach for routing silicon embedded capacitor. This approach has conducted to submission of a patent (application EP15189001.9) in the course of the year 2. The concept relies on the build-up of a 26/51

large network of elementary cells to build the capacitive element. The elementary cell (PCELL) is optimized in term of individual ESR/ESL such that the parasitic of the large network meet the specified target. Beside demonstration of the concept, a design methodology including parasitic predictive model and physical layout rules has been established. To support this work, a Multi Project silicon run has been designed and characterized in year1, a predictive model defined and correlated to experimental results, and a new layout approach defined. Figure 3.5 illustrates the benefit related to this design methodology compared to the native PICS design approach. Figure 3.5: Extracted ESR VS Capacitance value for different PICS layout approach. Blue dots are native PICS technologies. Other colours dots correspond to the new design approached developed in PowerSwipe. 4) Design, production and assembly of LV1, LV2 and HV test vehicles In year2, C-interposers embedding input/output capacitors, internal routing and landing patterns for PMIC and inductors have been designed (see figure 3.6). Two different mask sets have been produced, and corresponding silicon processed onto 2 different PICS nodes addressing both LV and HV voltage flavour (i.e. respectively <6V and <15V VUse). In parallel with the development of the C-Interposer, engineering tests have been conducted to demonstrate a PICS technology capable to withstand the HV voltage rating. Indeed the native PICS3 technology has an immediate breakdown voltage ~12V that gives sufficient lifetime margin for the LV demonstration, but is not capable for the HV. 27/51

Figure 3.6: Illustration of the C_Interposer layout: from left to right LV2, HV and LV1 To enhance the voltage robustness, the native PICS3 dielectric (ONO composite) has been resized in terms of thickness. A Time Dependant Dielectric Breakdowns campaign has been conducted on the different thickness variations to determine the best trade-off capacitive density/lifetime. This resulted in a new PICS technology node that corresponds to the PICS3HV flavour and that is capable to withstand the 15V with the appropriate mission profile (T /ducty cycle). In year 3, the silicon corresponding to the different demonstrators, LV1 (INSA) / LV2 (INFINEON) and HV (INFINEON) has been finalized and delivered. It is worth to note, that the LV1 was not embedding Through Silicon Vias technology and no EWLB packaging, contrary to the LV2 and HV modules. This resulted in shorter lead time. Finally, IPDIA assembled the PMIC on the different interposers (see figure 3.7). Figure 3.7: Illustration of the Cinterposer after PMIC assembly: from left to right HV, LV2 and LV1 The PowerSwipe project has enabled the development of a new layout approach to enhance PICS silicon integrated capacitor parasitic. The benefit of the approach was demonstrated up to the functional level on LV1 demonstrator. The approach has been generalized to other products in the field of the power processing and PDN decoupling. 28/51

IPDIA has also been developing a PICS technology flavour with higher breakdown voltage which is generalized as the PICS3HV platform that is now qualified for commercial designs. 5) Testing Main tests carried out: Measurement of inductors under probe, up to 110 MHz. Transient measurement of inductor current and voltage. Both single and coupled inductors (ITV2 and Demo2). Measurements on 1 st version of interposer. Test of inductors on PCB: Preliminary test on board at 100 MHz, using wideband fixed gain amplifier, to emulate power stage and load the inductor. Re-characterisation of all received devices using Kelvin probes. Figure 3.8. Setup of transient inductor measurement Figure 3.9 shoes the measured time domain waveforms for various frequencies and duty cycles (Test on board with wideband amplifier) for loosely coupled (k=0.4) inductors. These can be used to identify L, R and k values. 29/51

Voltage (V) Current (ma) D6.1.4, Final Management Report, March 2016 2 1.5 1 0.5 0-0.5 Integration result L1=48.85 nh, L2=44.91 nh, K=-0.31, R1=0.92, R2=0.51 Ohms at 50 MHz, R 2 1=0.976, R 2 2=0.978 60 40 20 0-20 -40-1 -60 0 5 10 15 20 25 30 35 40 45 50 Time (ns) VL1 (V) VL2 (V) IL1 MEASURE (ma) IL2 MEASURE (ma) IL1 CALC (ma) IL2 CALC (ma) Figure 3.9. Measured time domain waveforms 30/51

WP4 System Integration Work Package Objectives Demo1 Integration and fabrication Demo1 Functional Testing ITV2/Demo2 Integration ITV2/Demo2 Functional Testing Demo1 Validation Demo1, ITV2 and Demo2 samples were fabricated and integrated as planned. The testing of the ITV2/Demo2 devices has been carried out (See below for further details). The functional testing of Demo1 was carried out as planned, however no device showed the expected functionality. Therefore it was required to adjust the objectives and planning. The forensic testing of the failed samples was carried out and it was decided to fabricate a second run of Demo2 devices addressing the issues identified. The validation testing was delayed accordingly. The updated objectives for the 6-month extension (Month 37 to Month 42) were: Fabrication/integration of Demo1 devices: Back-up run Functional testing of Demo1 back-up run devices Validation testing of Demo1 back-up run devices Continue functional testing of ITV2/Demo2 devices Progress towards objectives Task 4.1.1 System-in-Package Technology (embedded solution) Demo1 Developing a power supply in package (PSiP) solution containing a functional interposer including Through Substrate Vias (TSV), passive devices (Inductor & Capacitor) and the respective logic IC. By adapting ewlb technology in order to scope with the requirements of advanced CMOS technology (e.g. ultra low k, Thermal mismatch, etc.) in terms of stress and strain adjustment an optimum Frontend/Backend interface will be achieved. The SiP technology is aimed to be scalable to sub 28 nm technologies. Task 4.1.2 System-in-Package Technology (flipped solution) ITV2-Demo2 Developing a power supply solution containing LC substrate including passive devices (Inductor & Capacitor) and the respective logic IC based on an intermediate test vehicle). This test vehicle is used to show the principal system feasibility by early functional and reliability characterisation. For the demonstrator the PMIC will be microbumbed onto this functional fan out substrate. With monolithic integrated inductors and capacities. Task 4.2: Characterisation and reliability analysis of individual components and Demo1A Board level characterisation according to defined electrical and reliability requirements to evaluate the manufacturability, functionality and reliability is performed on the individual components (inductors, trench capacitors and interposer) and the whole demonstrator system. Development of an adequate application test board and verify the performance in the test board in real automotive environment. Result will be an assessment whether this will fit into automotive environment. 31/51

Task 4.3: Forensic testing Identify the issues causing non-functional Demo1 samples. Significant results Demo1 The Demo1 (both HV and LV) samples were packaged using the ewlb (Embedded Wafer Level BGA) technology at Infineon Regensburg. Figure 4.1 shows a cross-section diagram of the ewlb integration of PMIC (LV/HV), inductor on Si interposer with capacitors. Figure 4.1 ewlb integration of Demo1 devices Figure 4.2 shows the fabricated devices on virtual wafer. Figure 4.2. HV & LV 3A527029 wafers ITV2-Demo2 Major tasks by Ampere lab on WP4 were the setup of the measurement test-benches and the actual measurements on the demonstrators. Several measurements were carried out to assess the performances of the demonstrators and validate the design approach. The converter was first tested as a standalone, validating its functionality and allowing for a first performance measurement. A specific test-board has been designed for this purpose, and the functionality of the chip was validated. A picture of the on-board converter is presented in the figure below. Note that due to physical constraints, decoupling capacitors can not be too close to the IC, limiting the effectiveness of these decoupling capacitors. Furthermore this type of assembly requires a lot of area. 32/51

Figure 4.3: Microphotograph of the board assembly. Following these preliminary tests, the integrated circuit was reported onto the passive interposer, making it a 3D assembly with a more compact full converter. The 3D assembly configurations were processed by IPDiA. Specific test-boards have then been developed, as well as an automated testbench that allows for testing the converters over an important number of frequency, duty cycle and load current values. A full characterization of the samples has then been carried out. The superiority of the 3D assembly over the board assembly was demonstrated. The advantage of the cascode power stage has also been validated by measurements. Pictures of the 3D assembly and test-board are presented in the figures below. Figure 4.4: Left: 3D assembly connected to the test-board. Right: 3D assembly test-board Validation Component-level reliability (CLR) of the Silicon inductors and board-level reliability (BLR) of the ewlb packages for automotive applications was carried out. The CLR involved thermal cycling of Tyndall s silicon inductors with automotive load profile for component level. 20 inductor samples were built, packaged and measured. 1000TC were performed, no optical damage detected. However the degradation was higher than expected. Therefore this degradation of impedance must be covered by control IC. The results of the test show that Tyndall s silicon inductors fulfil automotive requirements at component level. The BLR involved thermal cycling of the ewlb192 (pitch 0.5mm) package with and without underfill. Test boards were subjected to thermal cycling (Temperature range -40 C/+125 C. 33/51

Holding time at high/low temperature: 30 min. Ramp up/down time <1 min using 2 chamber system). The test results show that ewlb192 does not fulfil automotive requirements without underfill. The packages with underfill show an improvement of mean time to failure to approx. 3700TC. Considered as improved variant, however still not in target for potential automotive ECUlevel applications. Figure 4.5: Test results after 1000TC. Left: With underfill. Right: Without underfill Forensic Testing. Identify failure mechanisms leading to LV2 and HV non functionality Finally, in Year3 and Year4, systematic functionality issues (OPEN) have been detected on the HV and LV2 demonstrators (embedding TSVs and packaged with EWLB) while LTV1 was functional and performing as expected. A first failure analysis campaign did reveal on the initial run, an insufficient copper filling within the TSVs that was a direct cause for the OPEN. Cracks were also observed on the interposer backside revealing a large level of stress built between the RDL and the backside deeper copper trace. This has never been seen on other IPDIA products implementing TSVs, and therefore it is likely due to the interaction with the packaging (see figure 4.6). 34/51

Good die Bad die Figure 4.6: Physical analysis of the TSV (lot MH3496) after assembly. Left inset corresponds to visual inspection after side polishing, right inset to SEM inspection. An ultimate C-interposer silicon run was produced by IPDIA for the LV2. For this run IDPIA improved the copper coverage on the backside of the wafer and did implement systematic testing of dummies TSV-intensive structures on the wafer backside. Dies having proper continuity have been populated with the remaining LV2 PMIC. However, after packaging continuity issues (OPEN) were observed on all the samples. IPDIA has been conducting an additional FA campaign on some of the failing chains. IPDIA concluded that the copper filling was improved and behaving according expectations. However non-critical delamination re-occurs on the wafer backside (as observed on initial run). A critical delamination systematically occurs on the interface between the TSV and the front side routing of the interposer. Considering the aspect of the bottom of the TSV, it appears that a large level of stress is built-up (membrane is strained to a concave shape whereas it is normally observed flat after processing). It is recalled that the analysed structures was electrically tested OK prior to the assembly. This demonstrates an interaction between the TSV and the packaging process, resulting in too large level of stress causing catastrophic failures. 35/51

Improved copper Via bottom strain Overview on critical bottom crack Top crack already observed on run1 Figure 4.7: FA analysis of the TSV resulting from the second delivery run. It can be seen that copper integrity is confirmed. However delamination occurred on both interfaces with minor electrical impact on the backside and major electrical impact on the front side (bottom of via). 36/51

LV2 and HV demonstration have been hampered by continue issue. The causes of the different failure mechanisms have been analysed and are all related to failures in the TSV structure. IPDIA has demonstrated that the mechanisms related to discontinuity of coper in the TSVs could be resolved. However, another mechanism related to stress build-up during packaging could not be resolved in the course of the project. This would require further collaboration with INFINEON, in order to optimize the process stack, and define specific DFM rules. 37/51

WP5 - Dissemination Web site and LinkedIn Group The Web site (http://www.powerswipe.eu) was kept active during the course of the project. All public deliverables are uploaded to the Downloads page. Furthermore, a list of all publications and presentations is kept in the Results page, including Digital Object Identifier links to allow access to those with subscriptions. The LinkedIn Power Supply on Chip (PwrSoC) has continued growing and now has more than 80 active members. Tutorials On March 2015, as part of the APEC (Applied Power Electronics Conference and Exposition) in Charlotte (North Carolina), the PowerSwipe consortium presented a Professional Development Seminar on Power Supply on Chip, which was well attended with over 100 attendees. The PowerSwipe consortium also organised a two day ECPE PowerSoC workshop on Micropower Electronics: Powering Low-Power Systems which took place in Munich on June 16-17, 2015. Papers and presentations PowerSwipe has been very active disseminating the results of the project during the course of the project and especially during the final year. We have presented the results of PowerSwipe research at nine international conferences. We have also submitted 2 peer-reviewed papers which have already been accepted for publication. The following is the list of titles presented/published in Y3 and the six-month extension (for the full list of publications and bibliographical details, check D5.2.2, Final Dissemination Report ): Papers (Published or accepted for publication) Neveu, F.; Allard, B.; Martin, C.; A review of state-of-the-art and proposal for high frequency inductive step-down DC DC converter in advanced CMOS, Analog Integrated Circuits and Signal Processing, Vol. 87, Issue 2, May 2016, pp. 201-11. Neveu, F.; Allard, B.; Martin, C.; Bevilacqua, P.; Voiron, F. A 100 MHz 91.5% Peak Efficiency Integrated Buck Converter With a Three-MOSFET Cascode Bridge, IEEE Transactions on Power Electronics, Vol. 31, Issue 6, June 2016, pp. 3985-8. Anthony, R.; Wang, N.; Casey, D.P.; Ó Mathúna, C.; Rohan, J.F. MEMS based fabrication of high-frequency integrated inductors on Ni Cu Zn ferrite substrates, Journal of Magnetism and Magnetic Materials, vol 406, 15 May 2016, pp. 89-94. Anthony, R.; Ó Mathúna, C.; Rohan, J.F. Permalloy Thin films on palladium activated selfassembled monolayer for magnetics on silicon applications, Procedia Physics, vol 75, 2015, pp. 1205-13. Anthony, R.; Shanahan, B.J.; Waldron, F.; Ó Mathúna, C.; Rohan, J.F. Anisotropic Ni Fe B films with varying alloy composition for high frequency magnetics on silicon applications, Applied Surface Science, vol 357, part A, 1 December 2015, pp. 385-90. 38/51

Cortes, J.; Svikovic, V.; Alou, P.; Oliver, J.; Cobos, J.A. v1 concept: designing a voltage mode control as current mode with near time-optimal response for Buck-type converters, IEEE Transactions on Power Electronics, Vol. 30, Issue 10, October 2015, pp. 5829-41. Conference Proceedings APEC 16 (Long Beach USA, 20-24 March 2016) Tyndall: Large-Signal Power Circuit Characterization of on-silicon Coupled Inductors for High Frequency Integrated Voltage Regulation Infineon Austria: A Mixed-Signal Ripple-Based Controller for a 16V, 10MHz Integrated Buck Converter AACD 16 (Villach, Austria, 26-28 April 2016) Lab Ampere: Heterogeneous Integration of High-Switching Frequency Inductive Converters MNE'15 (The Hague, September 21-24) Tyndall: Electrochemical process for fabrication of laminated micro-inductors on silicon ECCE 2015 (Montreal, 20-24 September) Tyndall: High Efficiency on-silicon Coupled Inductors using Stacked Copper Windings EuMW, (Paris, 6-11 September) IPDiA: New Ultra Low ESR Mosaic PICS Capacitors for Power Conversion ICM 2015 (Barcelona, 5-10 Jul) Tyndall: Permalloy Thin Films on Palladium Activated Self-Assembled Monolayer for Magnetics on Silicon Applications IWIPP'15 (Chicago, 3-6 May) IPDiA: High-Density Capacitors for Power Decoupling Applications ICECS 2014 (Marseille, 7-10 December) Lab Ampere presentation (WYMPhD Forum) 3DIC (Kinsale, Dec 14) Tyndall: Advanced Processing for High Efficiency Inductors for 2.5D/3D Power Supply in Package (Best Poster Award) PwrSoC 2014 (Boston, 6-8 October) Presentations: IFAT, IPDiA, CEI-UPM, Lab Ampere E-posters: IFAT, Lab Ampere 39/51

WP5 - Exploitation All partners have been continuously looking at potential exploitation routes for the knowledge and technologies developed through PowerSwipe. The following figure shows the PUDF spreadsheet, with the list of potential project outcomes identified so far. Description Type Sector Process for fabrication of racetrack inductor Multi DC-DC converter PMIC with Passives IPR Exploitation Lead Partner Commercial Power Electronics Own/Licence Tyndall Adv. Knowledge Commercial Power Electronics, Automotive, General Own/Licence Integrated Magnetic Design Tool Commercial CAD Licence UPM Component embedding Si trench based capacitors SiP for multi DC-DC Converter PMIC with Passives IFAT Commercial Power Electronics Own/Licence IPDiA Adv. Knowledge Commercial Power Electronics, Automotive, General Power Electronics, Automotive Power Electronics, Automotive, General Own/Licence Microcontroller with embedded voltage controller Commercial Own Multi DC-Dc converter design used in next generation Aurix Commercial Own Microcontroller family Figure 5.2. List of identified project outcomes from PUDF IFX Bosch Based on this list, the PowerSwipe consortium has produced an Exploitation Plan (Deliverable D5.3). Two US patents on DC-DC converters have been filed by Infineon Austria and one European patent application has been submitted by IPDiA. Intellectual Property Rights: Two US patent applications on DCM regulation with digitally estimation of the zero crossing event by partner IFAT. Patent pending (EP15189001.9) on novel layout approach to lower the capacitance ESL/ESR, leveraging lithographic capabilities and combining a self-recurring capacitive network with localized contacts. IFAT 3.2.3 Project management during the period Management tasks included the organising of consortium meetings, internal reporting on work progress (monthly) and submission of deliverables. Project meetings were organised on a regular basis, as well as WP specific meetings and discussions: Executive Steering Committee meetings were carried out on the first Tuesday of every month via teleconference with the support of multimedia sharing facilities (WebEx) 40/51

Consortium meetings every six months: o 4 th Six-monthly meeting: Villach (IFAT), 20-21 October 2014 o 5 th Six-monthly meeting: Stuttgart (Bosch), 22-23 June 2015 WP-specific meetings were organised when required: o WP2: Modelling meeting at UPM (Madrid) attended by Lab Ampere on 11 October 2014. The project consortium keeps a Document Repository where all common documents and internal reports are shared. Problems which have occurred and how they were solved or envisaged solutions The inductor technology transfer from Tyndall to IFX (Task 3.2) has resulted more problematic and time consuming that originally planned. The issues identified were solved during Year 3 and this activity is now finalised. Deliverable D3.3 describes the work carried out. Changes in consortium No changes Impact of possible deviations from the planned milestones and deliverables The PowerSwipe project progressed according to the existing version of the plan (DoW v. March 2015). Demo1, ITV2 and Demo2 samples were fabricated and their functional testing commenced in June 2015. The ITV2/Demo2 samples are working as designed and based on the measurement results obtained so far, they are the best in class for high frequency PwrSoC. The Demo1 devices however did not show any functionality during testing. Furthermore, test devices with daisy-chain structures show high resistance or no connectivity, therefore indicating issues with interconnects within the ewlb package. This issue was flagged by IFAT in early August as soon as it became evident. The consortium held a number of urgent discussions to understand the issues, agree an investigation plan and consider contingencies. Corrective actions and contingency plan During August 2015, the consortium started the task of Forensic Testing of Demo1 to analyse the devices and investigate the cause of these failures. This task was finalised by the middle of September. A confidential report was prepared (D4.4, Failure Analysis ), including integration design recommendations to address the identified causes of failure. The consortium has enough back-up parts fabricated in WP3 to attempt a new integration run. After considering a number of contingency plans to carry out this back-up integration, the consortium decided to fabricate a full ewlb re-run. Six-month extension In order to achieve the original objectives of the project, the following tasks need to be undertaken during a six-month extension (Month 37 to Month 42: 1 st October 2015 to 31 st March 2016): Completion of the Forensic Testing Fabrication of Demo1 devices using selected integration/assembly method from the above list 41/51

Functional testing by IFAT Validation by Bosch The request for a six month extension was approved by European Commission in September 2015. A new DoW (v. Sep 2015) has now replaced the previous DoW (v. March 2015). Changes to Description of Work including tasks, milestones and deliverables The main activities of the project during the requested extension will be on WP4 for Integration and Testing. WP1 and WP3 are now finished. The activities of WP2 will wait for the results of the functional testing to further improve the models developed during the course of the project. The following Gantt chart shows the updated plan for WP4. The new Task 4.3 Forensic Testing continued until the middle of September 2015. The back-up fabrication run (Task 4.1) for the full ewlb re-run was started in October and finally the functional and validation testing (T4.2) on the new Demo1 samples was carried out. As the new back-up run samples did not show any functionality, a second Forensic Testing (Task 4.3) was carried out to identify the issues with these samples and to issue a set of recommendations for successful integration. Due to these changes, a new version of the DoW was agreed in September 2015, with new dates for some of the existing deliverables. Also two new deliverables were added, one D4.4 to report the results of the Forensic testing and an updated version of D4.1. Deliverable Title Current due date 6-month extension D1.4 Optimised system architecture Description 33 42 D1.5 Optimised block-level specification 33 42 D2.6 Analysis/optimisation of int. passives 36 41 D2.7 Multi-disciplinary platform for PwrSoC 36 41 design D4.1.2 Demonstrator 1 Back-up run (new) 39 D4.3 Demonstrators analysis and characterisation 36 41 D4.4 Forensic Testing. 3D integration (new) 36 recommendations D5.2.2 Final Dissemination report 36 42 D5.3 Technology implementation and exploitation plan 36 42 42/51