DE Digital Technology GmbH

DE DIGITAL TECHNOLOGY GMBHDE DIGITAL TECHNOLOGY GMBH - is a global financial and technology center that develops, whose main taskimplements isand whosecommercializes mainnew taskprojects isin the developmentfinance, implementationcommunications, and commercialization of innovative projects.The company includeshigh-tech a consortiumspaces. ofThe investorsgroup fromis abased varietyout of industries,focused on creating and promoting quantum, 3D, biometric, opticalBerlin.

satellite, medical, chemical, biology and information technologies, as well as technologies artificial intelligence, measurement, security and digital transmission multimedia data. was created in Berlin by a group of specialists from finance, innovation, communications, and high-tech.

Areas of activity

Expert evaluation of projects

in the field of IT-technologies for the purpose of further development and capitalization. Creation of a global

"Center of Competence" for high technologies

Attracting investment, Organizing and conducting

scientific conferences around the world Student exchange

between universities higher education institutions

Development of global high-tech business

Engineering and finance support for high-tech projects

DE DIGITAL TECHNOLOGY:

has a permanent technology partner with a strong scientific and technical,

technological and resource capacity independently conducts analysis knowledge (technologies) and carries out their assessment, creates and enhances their value and significance conducts commercialization technologies (researches and developments) transfers technologies - transfers the results of research and development for their commercial and non-commercial use has access to various sources of financial support innovative projects

Partnership

Joint cooperation agreement,

strategic planning of joint projects, synchronization of projects with investment programs, consulting, methodological and informational support of investment projects, assistance in implementing projects on domestic and global markets

INTERNATIONAL CENTER FOR SCIENCE AND EDUCATION (ICSU)

TECHNOLOGY TRANSFER AND COMMERCIALIZATION

Created on the basis of the Moscow Institute of Physics and Technology (National Research University).

The activities are aimed at: Creation of infrastructure providing all stages of the innovation process (from basic research to product sales) Commercialization of breakthrough scientific achievements in the interests of all participants of the innovation process: authors, scientific institutions, customers of developments, investors, personnel training in new directions, researches and technological developments for the world's leading companies, export of technological and educational services and expert evaluation of the applicability of technologies on the sites of partner countries, primarily in the EC

DE DIGITAL TECHNOLOGY GMBH as a full partner will

to ensure the integration of ISTC into the international innovation

and investment community and coordinate its international investment activities, is vested with the rights to create innovation enterprises of world class based in

The company has the right to create world-class innovative enterprises based in the territory of countries that consume innovative products.

Partnership between MIPT and De Digital Technology.

Companies closely cooperate with each other and develop joint projects, technologies and provide various services. List of services provided by MФТИ :

Autonomous and distributed energy ,microprocessors and control devices ,satellite communications and navigation ,hard to recover hydrocarbons, medical equipment and pharmaceuticals, radio-location technology,two-dimensional materials and graphene quantum technologies, biophysics and life extension mechanism, genome technologies,artificial Intelligence and Digital Technologies

DE Digital Technology GmbH List of services provided by МФТИ

R&D projects in the field of high technology. Software development for the technological process. Financial and economic analysis Business development and market analysis. The project center performs the tasks and all necessary functions advisory council

Portfolio of projects

In cooperation with MIPT, there are more than 500 ongoing and potential projects. At the moment the current projects:

Quantum technologies, 3D technologies, artificial intelligence technologies, biometric technologies, optical technologies, measurement technologies, satellite technologies, digital data transmission and multimedia technologies. Security technologies , medical technologies , chemical technologies , biological technologies , information technologies.

Quantum Technologies . Coherent optical systems . For a high-speed neural network. Coherent optical systems with 95% accuracy can recognize images at the speed of light. 95% accuracy can recognize images and operate literally at the speed of light. The speed of computation is decisive factor for algorithmic trading, especially for high frequency trading (HFT), which is characterized by high computing speeds and high turnover rates. The trader with considerable delay makes trading decisions based on outdated information. The one millisecond advantage in trading applications can cost a large brokerage firm $100 million a year. That's why low-latency trading is of particular value to the investor: it allows for the fastest possible decisions as quickly as possible; fast systems today can execute transactions from traders' desktops to data centers in a few milliseconds. When investing in technology to process information faster, the entire cycle of event and action analysis is reduced to a couple of milliseconds. Machine learning is currentlymachine learning is widely used in trading. Systems Price forecasting and trading systems neural network based systems that use technical analysis indicators as inputs, can be used to achieve competitive results. A laser interferometry scheme to accelerate computation with direct coupling of a pre-trained neural network can be used to increase the speed of any type of data analysis. Considering time-critical fields, such as the low-latency trade-off described above.

A new basis for superconducting electronics

In 2016, scientists from the laboratory, together with a group of scientists from Moscow State University proposed a fundamentally new type of memory cells based on based on superconductors - such memory can work hundreds

hundreds of times faster than the types of memory devices common today. The main goal of the laboratory is to obtain scientific results in the field of topological

The main goal of the laboratory is to obtain scientific results in the field of studying topological quantum phenomena in superconductor contacts with semiconductor and ferromagnetic nanowires and development of new quantum-mechanical devices. Key elements of superconducting electronics: superconducting nanowires, Josephson junction based on nanowires, nanosensor devices, controlled Josephson devices with ferromagnetic interlayers, SCVIDs and NANOCVIDs, digital / analog / neuromorphic superconducting quantum cells, qubits and topologically protected superconducting devices.

Superconductor quantum processor

The lab is currently working on the integration of superconducting quantum circuits and developing the underlying technology for quantum computers/simulators. The main goal of the lab is to build a prototype of a full-scale multicube quantum processor, which will be the basis for further integration. The prototype will be built on the basis of MIPT. The prototype will consist of 4 qubits with cross-links and will emulate a Hamiltonian with an appropriate dimensionality of 16x16. In the development of quantum technologies, the IKS group is working closely with MISIS, Bauman University, the Institute of Solid State Physics of the Russian Academy of Sciences, and the Institute of Solid State Physics of the Russian Academy of Sciences. Institute of Solid State Physics of the Russian Academy of Sciences and the Institute of Automatics. of D-WAVE, Google, INTEL, IBM, etc.

3D microchips

At the very beginning of the new century, chip-based technologies have gained an unprecedented spread in the global market. The application of microchips in such industries as the Internet of Things, autonomous driving of vehicles. Industry 4.0, the development of artificial intelligence technologies, health care and consumer goods increase the demand for the creation of advanced technological production of microelectronics.Such an advanced technology is the 3D volumetric chip semiconductor micro-assembly, in which two or more layers of active electronic components are arranged on top of each other and connected vertically and horizontally. Thanks to this layout, devices running on 3D chips exhibit high performance and power, while occupying space saving compared to all alternatives. alternatives.

Currently, 3D assembly is the only advanced technology, that can increase the power of a chip by reducing its size. The advantages of this technology compared to standard 2D interconnects are: size reduction by 35%, improving power and signal by 40%, and reducing costs by 45%. Overall, the 3D assembly is characterized by high functionality and performance, low power consumption, manufacturing flexibility, faster time to market and low cost. In view of the above of the circumstances described above the research, the research, development and optimization of this technology is of paramount importance importance.

Thanks to close cooperation with the Fraunhofer ASSID Institute, part of the

Fraunhofer ICM, which is recognized as one of the most advanced institutes for 3D technology worldwide, the idea of organizing the production of 3D microchips was born. The Moscow Institute of Physics and Technology (MIPT) plans to create a research and development center, as well as small-scale production to work out the technology of 3D assembly. DE Digital Technology GmbH, in turn, together with Midgard Technologies plans to build a 3D microchip production facility, which will make it possible to integrate various components and technologies into a single system.

This will enable the integration of various components and technologies into a single chip. The production complex is planned to be organized in Dresden, Germany, as part of the Dresden, Germany, as part of the Silicon Saxony

Artificial Intelligence Technologies

Intelligent hardware and software solutions for real-time photo and video processing. Currently, the laboratory staff is developing intelligent systems: unmanned vehicles, weaponry, video recording, vehicle detection and localization, medical image analysis. Such intelligent systems are based on the technology of detection, localization and classification of objects in real-time mode. The proposed technology is based on algorithms of artificial neural networks. An artificial neural network is a sequence of connected and interacting simple processors (artificial neurons) - a simulation model created based on the principles of interaction of nerve cells in the brain. For effective pattern recognition a convolutional neural network is created - a special architecture of artificial neural network that performs the transition from basic image elements to higher level elements.

Intelligent hardware and software solutions for real-time photo and video data processing, including digital cameras, video recording systems, and guided chassis have been created based on the convolutional neural network, Intelligent image processing systems for diagnostics of skin diseases. Medical image analysis system,

as a separate product of an intelligent hardware and software solution, the proposed technology allows the independent monitoring of suspicious pigs. The proposed technology allows independent monitoring of suspicious pigmented lesions. Although the final diagnosis is made by a dermatologist, considerable time and effort can be saved by Screening techniques that are available for both patient self-management and support to primary care physicians and other medical The use of screening techniques can save a great deal of time and effort by using them for patient self-management. The screening techniques are patient- or patient-applicable and can also be used to support primary care physicians and other medical personnel without special education.

Virtual Synchronous Machine

with artificial intelligence VSM AI

The project under consideration is based on the creation of a decentralized distributed energy system based on multi-agent systems with artificial intelligence, by empowering the storage units, power receivers and generating devices with the functions of an intelligent an intelligent agent able to take decisions at a lower level, to teach itself and organize itself into freely scalable networks, realizing the principle of PLUG&PLAY (IoEn 2.0).

IoEn 2.0 is formed as a network structure of power converters (Power convertor PC) and electrochemical storages to realize free circulation of electric power between intelligent agents in P2P (Pear to pear) systems. The main task of IoEn 2.0 is free equilibrium power distribution (energy at short time intervals) in horizontal (P2P) electric power systems.

A significant result is the development of hardware for the control of complexly closed micro-power systems with a high degree of uncertainty. The main goal is the development of a virtual synchronous machine with VSM AI. The stability of the parallel operation of VSM is a hot topic at the present time for leading research and development centers worldwide. In the development, the laboratory is working closely with NTI EnergyNet and Russian high-tech companies.

An operating system for power machines with artificial intelligence GFP

At the heart of the project under consideration is the development of the Grid Forming Platform (GFP) operating system for power machines with artificial intelligence. As is known, the economic mechanism of the market is realized through electricity trading and change in power per unit time (flexibility) at certain time intervals. Implementation of the project will provide the primary regulation of small power system parameters without the use of expensive storage systems and converter technology.In turn, this opens up great opportunities for the development of decentralized energy systems, makes available and widespread electricity and microgeneration based on renewable energy sources (RES), thereby developing the retail consumer market. The platform under development will not only form an infrastructure for transactional energy within a single microgrid, but also unite multiple distributed energy sites for free trade of electricity. Compliance with global trends in the transformation of traditional energy towards decentralized energy will make it possible to achieve the dynamic stability of the system without a system operator. A significant result is the development of GFP software for the management of complex closed microgrid systems with a high degree of uncertainty

Interactive biometric identification

The proposed project is based on a new system of personal identification, based on the verification of a person by analyzing the individual characteristics of his nervous system, adapted for use in open systems on untrusted devices. The human nervous system is characterized by its uniqueness. There are no predictive models of the human nervous system. The parameters of the human response are due to the individual characteristics of his or her nervous system, so his or her response cannot be modeled or substituted. On this basis, we can safely state that the reaction of any individual is his dynamic identifier. The implementation of biometric identification is as follows: The DPC (a trusted device) synthesizes a random visual stimulus for the person in question. A DPC (a trusted device) synthesizes a random visual stimulus, a mobile (untrusted) device displays a stimulus that is perceived by a human nervous system, a human reflexively reacts to the stimulus (by eye movement, pupil contraction, pulse change, movements), individual reaction features are recorded by a built-in camera of a user device, the DPC calculates a biometric identifier based on the "stimulus-reaction" pair and performs vital verification of the person.

Optoelectronic instrumentation for small remote sensing spacecraft OEE-902046

The project is based on the development of OEE-902046 optoelectronic instrumentation for small satellites which is intended to be mounted on the small satellites for the purpose of obtaining high resolution images of the Earth surface in the visible and near infrared spectral bands during the remote sensing tasks. OEE-902046 includes two high resolution optoelectronic cameras: a panchromatic camera (OEC-902146) and a multispectral camera (OEC-902246), achieving a special resolution of 1 m (panchromatic) and 4 m (multispectral) at an altitude of 900 km. The OEE-902046 also contains a control and switching unit (CCU). The CCU includes a 128 GB memory unit, facilitates data exchange with the spacecraft control system via the CAN-2B interface, generates cyclograms (command sequences) and commands for camera control, receives camera telemetry and image data, records image data to the memory unit and transmits them to the downlink of the spacecraft (via a special data protocol).

Power consumption Power consumption of the CCU in operating mode with the RAM block does not at most 30 W. The mass of CCU is about 3 kg. The dimensions are 200 x 200 x 70 mm.

IGEO-sensors of the new generation for seismic exploration

Oil and gas are among the most important fuels used by mankind. However, most of the sources where it was easy to extract oil are now depleted. Therefore, resource companies are beginning to extract raw materials in hard-to-reach places that require state-of-the-art technology. The previous generation technologies - electro-mechanical and MEMS sensors - turn out to be inefficient and do not allow achieving the desired results. This is due to insufficient sensor sensitivity, high noise level, narrow frequency operating range, low conversion coefficient, sensor sensitivity to tilting during installation and lack of possibility to receive different types of waves and analyze them. At the heart of the project under consideration is the organization of the production of broadband highly sensitive molecular-electronic IGEO sensors. The IGEO technology, based on silicon The IGEO technology based on silicon chips makes it possible to produce a more affordable and precise product than competitors' products. 1 IGEO sensor replaces 12 standard sensors. The advantages for the consumer: savings in operating costs, the ability to obtain more reliable data and the ability to integrate the technology into existing systems. Thus, By using the IGEO, the user can reduce the number of sensors By replacing a group of 12 geophones with one IGEO.

Oil and gas are among the most important fuels used by mankind. However, most of the sources where it was easy to extract oil are now depleted. Therefore, resource companies are beginning to extract raw materials in hard-to-reach places that require state-of-the-art technology. The previous generation technologies - electro-mechanical and MEMS sensors - turn out to be inefficient and do not allow achieving the desired results. This is due to insufficient sensor sensitivity, high noise level, narrow frequency operating range, low conversion coefficient, sensor sensitivity to tilting during installation and lack of possibility to receive different types of waves and analyze them. At the heart of the project under consideration is the organization of the production of broadband highly sensitive molecular-electronic IGEO sensors. The IGEO technology, based on silicon The IGEO technology based on silicon chips makes it possible to produce a more affordable and precise product than competitors' products. 1 IGEO sensor replaces 12 standard sensors. The advantages for the consumer: savings in operating costs, the ability to obtain more reliable data and the ability to integrate the technology into existing systems. Thus, By using the IGEO, the user can reduce the number of sensors By replacing a group of 12 geophones with one IGEO.

Oil and gas are among the most important fuels used by mankind. However, most of the sources where it was easy to extract oil are now depleted. Therefore, resource companies are beginning to extract raw materials in hard-to-reach places that require state-of-the-art technology. The previous generation technologies - electro-mechanical and MEMS sensors - turn out to be inefficient and do not allow achieving the desired results. This is due to insufficient sensor sensitivity, high noise level, narrow frequency operating range, low conversion coefficient, sensor sensitivity to tilting during installation and lack of possibility to receive different types of waves and analyze them. At the heart of the project under consideration is the organization of the production of broadband highly sensitive molecular-electronic IGEO sensors.

IGEO-sensors of the new generation for seismic exploration

Oil and gas are among the most important fuels used by mankind. However, most of the sources where it was easy to extract oil are now depleted. Therefore, resource companies are beginning to extract raw materials in hard-to-reach places that require state-of-the-art technology. The previous generation technologies - electro-mechanical and MEMS sensors - turn out to be inefficient and do not allow achieving the desired results.