MaxEye Technologies is a Bangalore based company. We specialize in providing solutions and sevices in Wireless, Signal Processing, Machine Vision, VLSI and LabVIEW and TestStand based automation services. We have strong expertise in developing test and measurement solutions for Automotive infotainment test system and DTV Testing.
We are an Alliance Partner of National Instruments. MaxEye Technologies provides complete in-car infotainment test solution using NI PXI hardware, Software and MaxEye DVB toolkits.
MaxEye Technologies enables multiple Digital Video and Audio broadcasting standards using single hardware platform. This reduces testing time and cost significantly compared to traditional testing.
Introduction to Software Defined Radio (SDR)Pamela O'Shea
For less than $20 anyone can listen to the airwaves! In this workshop, we will look at what is around us in the airwaves, including frequency scanning, pagers, airplanes, remote controls and more. Please see associated worksheet for the exercises.
SCA To Date and Motivation for Change. These slides will discuss why the JTRS Program Executive Office (JPEO) is aggressively procuring Software Defined Radio (SDR) consortium and industry assistance to spearhead a high impact evolution of the Software Communications Architecture (SCA) intended to deliver better radio performance along with a smaller footprint for waveforms and radio software. The webcast audience will learn about innovative SCA change proposal details and identified opportunities for near term radio performance impact with rapid market availability of these new capabilities via highly motivated COTS SDR software and development tool vendors.
A Glimpse into Developing Software-Defined Radio by PythonAlbert Huang
Software-defined radio~(SDR) has been emerging for many years in
various fields, including military, commercial communication
systems, and scientific research, e.g. space exploration. GNU Radio
is an open source SDR framework written in Python. This talk will introduce from basic concept of software-defined radio and various
front-end hardware, and then illustrate how to use Python to develop
SDR.
Universal software defined radio development platformBertalan EGED
Award winning presentation at a NATO RTO IST symposium in 2006 on Universal Software Defined Radio (SDR) Development Platform and its use for prototyping radar system and spectrum monitoring receiver. Till this time I made several presentations on the topic, but this is the original version from 2006.
MaxEye Technologies enables multiple Digital Video and Audio broadcasting standards using single hardware platform. This reduces testing time and cost significantly compared to traditional testing.
Introduction to Software Defined Radio (SDR)Pamela O'Shea
For less than $20 anyone can listen to the airwaves! In this workshop, we will look at what is around us in the airwaves, including frequency scanning, pagers, airplanes, remote controls and more. Please see associated worksheet for the exercises.
SCA To Date and Motivation for Change. These slides will discuss why the JTRS Program Executive Office (JPEO) is aggressively procuring Software Defined Radio (SDR) consortium and industry assistance to spearhead a high impact evolution of the Software Communications Architecture (SCA) intended to deliver better radio performance along with a smaller footprint for waveforms and radio software. The webcast audience will learn about innovative SCA change proposal details and identified opportunities for near term radio performance impact with rapid market availability of these new capabilities via highly motivated COTS SDR software and development tool vendors.
A Glimpse into Developing Software-Defined Radio by PythonAlbert Huang
Software-defined radio~(SDR) has been emerging for many years in
various fields, including military, commercial communication
systems, and scientific research, e.g. space exploration. GNU Radio
is an open source SDR framework written in Python. This talk will introduce from basic concept of software-defined radio and various
front-end hardware, and then illustrate how to use Python to develop
SDR.
Universal software defined radio development platformBertalan EGED
Award winning presentation at a NATO RTO IST symposium in 2006 on Universal Software Defined Radio (SDR) Development Platform and its use for prototyping radar system and spectrum monitoring receiver. Till this time I made several presentations on the topic, but this is the original version from 2006.
SDR Training with HackRF - Tonex TrainingBryan Len
Length: 3 Days
SDR Training with HackRF, Advanced Software Defined Radio Training is a 3-day hands-on advanced SDR training course, Software-Defined Radio Development with GNU Radio utilizing HackRF One. The 3-day advanced SDR covers both hypothesis and application of SDR utilizing HackRF One.
.
SDR Training with HackRF. Advanced Software Defined Radio Training.
Participants will learn about:
Software Defined Radio and Digital Signal Processing
Theory and practice with hands-on SDR implementations using the Universal Software Radio Peripheral (USRP) SDR platforms
Necessary SDR signal processing building blocks, SDR application development using Python and C++ concepts required for GNU Radio development
How to apply HackRF and GNU Radio
How to use and apply GNU Radio Companion (GRC)
Security applications of SDR and RF Vulnerabilities
Course Agenda
Principles of Signal processing and applied RF
Overview of SDR
Overview of GNU Radio
Overview of GNU Radio software libraries
Overview of GNU Radio Companion (GRC)
Overview of Python and C++
Overview of Linux
Overview of Universal software radio peripherals
SDR and GNU Radio modules
Systems using HackRF One
Assessments of physical RF devices
How to Fingerprint on RF spectrum?
Hunting signals
Hardware Hacking 101
Reversing and Instrumentation (embedded RF systems)
IoT Hacking with SDR
Overview of Wi-Fi and Bluetooth
Open source SDR LTE software / FM Radio
Principles of Radar detector
Principles of Remote Controlled Cars
SDR Offensive Security
Request more information regarding SDR Training with HackRF. Visit tonex.com for course and workshop detail.
SDR Training with HackRF - Tonex Training
https://www.tonex.com/training-courses/sdr-training-with-hackrf-advanced-software-defined-radio-training/
Hardware Accelerated Software Defined Radio Tarik Kazaz
Advanced 5G wireless infrastructure should support any-to-any connectivity between densely arranged smart objects that form the emerging paradigm known as the Internet of Everything (IoE). While traditional wireless networks enable communication between devices using a single technology, 5G networks will need to support seamless connectivity between heterogeneous wireless objects, and consequently enable the proliferation of IoE networks. To tackle the complexity and versatility of the future IoE networks, 5G has to guarantee optimal usage of both spectrum and energy resources and further support technology-agnostic connectivity between objects. This can be realized by combining intelligent network control with adaptive software-defined air interfaces. In order to achieve this, current radio technology paradigms like Cloud RAN and Software Defined Radio (SDR) utilize centralized baseband signal processing mainly performed in software. With traditional SDR platforms, composed of separate radio and host commodity computer units, computationally-intensive signal processing algorithms and high-throughput connectivity between processing units are hard to realize. In addition, significant power consumption and large form factor may preclude any real-life deployment of such systems. On the other hand, modern hybrid FPGA technology tightly couples a FPGA fabric with hard core CPU on a single chip. This provides opportunities for implementing air interfaces based on hardware/software co-processing, resulting in increased processing throughput, reduced form factor and power consumption, while at the same time preserving flexibility. This paper examines how hybrid FPGAs can be combined with novel ideas such as RF Network-on-Chip (RFNoC) and partial reconfiguration, to form a flexible and compact platform for implementing low-power adaptive air interfaces. The proposed platform merges software and hardware processing units of SDR systems on a single chip. Therefore, it can provide interfaces for on-the-fly composition and reconfiguration of software and hardware radio modules. The resulting system enables the abstraction of air interfaces, where each access technology is composed of a structured sequence of modular radio processing units.
Suppliers of Colour TV Trainer Kit, Mobile Phone Trainer Kit, AM/ FM Radio Trainer Kit, Oscilloscope / Demonstrator Trainer, Microwave Test Bench - Klystron Antenna, Advanced MIC Trainer, Microwave Test Bench - Klystron, Microwave Test Bench - Gunn.
Surf Communication Solutions provides of MoP (Media over Packet) Triple Play (Voice, Video, and Modem/Fax/Data) conversion solutions to communication equipment manufacturers. These solutions are provided in various integration levels: DSP software ; PTMC boards; DSP hardware/software; and PCI boards. http://www.surf-com.com
Design and implementation of sdr based qpsk transceiver using fpgaTarik Kazaz
Software-defined radio (SDR) technology enables
implementation of wireless devices that support multiple air interfaces and modulation formats, which is very important
if consider the proliferation of wireless standards. To enable such functionality SDR is using reconfigurable hardware platform such as Field Programmable Gate Array (FPGA). In this paper, we present design procedure and implementation result of SDR based QPSK modulator on Altera Cyclone IV FPGA. For design and implementation of QPSK modulator we used Altera DSP
Builder Tool combined with Matlab/Simulink, Modelsim and
Quartus II design tools. As reconfigurable hardware platform
we used Altera DE2-115 development and education board with
AD/DA daughter card. Software and Hardware-in-the-loop (HIL)
simulation was conducted before hardware implementation and
verification of designed system. This method of design makes
implementation of SDR based modulators simpler ad faster.
Index Terms—SDR, FPGA, QPSK, DSP Builder, NCO, RRC
Software Defined Radio Engineering course samplerJim Jenkins
This 3-day course is designed for digital signal processing engineers, RF system engineers, and managers who wish to enhance their understanding of this rapidly emerging technology. Most topics include carefully described design analysis, alternative approaches, performance analysis, and references to published research results. Many topics are illustrated by Matlab simulation demos. An extensive bibliography is included.
Design And Simulation of Modulation Schemes used for FPGA Based Software Defi...Sucharita Saha
Design of a BPSK and QPSK digital Modulation scheme and its implementation on FPGAs for universal mobile telecommunications system and SDR applications. The simulation of the system is made in MATLAB Simulink environment and System Generator, a tool used for FPGA design. Hardware Co-Simulation is designed using VHDL a hardware description language targeting a Xilinx FPGA and is verified using MATLAB Simulink. It is then converted to VHDL level using Simulink HDL coder. The design is synthesized and fitted with Xilinx 14.2 ISE Edition software, and downloaded to Spartan 3E (XC3S500E) board.
MaxEye Technologies provides complete DVB test and measurement solutions for testing the broadcast equpiments and receivers during manufacturing, design labs and automating the tests. The supported DVB Standards are DVB-T/T2/H, DVB-S/S2, DVB-C, ISDB-T/Tb, ATSC, ATSC-M/H, DAB/DAB Plus/T-DMB, DRM and DRM Plus. In addition to the digital standards we also support AM, FM and RDS. For more information contact ramesh@maxeyetech.com
This document describes the measurement configurations and procedures for DAB receiver testing using National Instruments PXI Vector Signal Generators and MaxEye DAB/DABPlus/T-DMB Signal Generation software.
SDR Training with HackRF - Tonex TrainingBryan Len
Length: 3 Days
SDR Training with HackRF, Advanced Software Defined Radio Training is a 3-day hands-on advanced SDR training course, Software-Defined Radio Development with GNU Radio utilizing HackRF One. The 3-day advanced SDR covers both hypothesis and application of SDR utilizing HackRF One.
.
SDR Training with HackRF. Advanced Software Defined Radio Training.
Participants will learn about:
Software Defined Radio and Digital Signal Processing
Theory and practice with hands-on SDR implementations using the Universal Software Radio Peripheral (USRP) SDR platforms
Necessary SDR signal processing building blocks, SDR application development using Python and C++ concepts required for GNU Radio development
How to apply HackRF and GNU Radio
How to use and apply GNU Radio Companion (GRC)
Security applications of SDR and RF Vulnerabilities
Course Agenda
Principles of Signal processing and applied RF
Overview of SDR
Overview of GNU Radio
Overview of GNU Radio software libraries
Overview of GNU Radio Companion (GRC)
Overview of Python and C++
Overview of Linux
Overview of Universal software radio peripherals
SDR and GNU Radio modules
Systems using HackRF One
Assessments of physical RF devices
How to Fingerprint on RF spectrum?
Hunting signals
Hardware Hacking 101
Reversing and Instrumentation (embedded RF systems)
IoT Hacking with SDR
Overview of Wi-Fi and Bluetooth
Open source SDR LTE software / FM Radio
Principles of Radar detector
Principles of Remote Controlled Cars
SDR Offensive Security
Request more information regarding SDR Training with HackRF. Visit tonex.com for course and workshop detail.
SDR Training with HackRF - Tonex Training
https://www.tonex.com/training-courses/sdr-training-with-hackrf-advanced-software-defined-radio-training/
Hardware Accelerated Software Defined Radio Tarik Kazaz
Advanced 5G wireless infrastructure should support any-to-any connectivity between densely arranged smart objects that form the emerging paradigm known as the Internet of Everything (IoE). While traditional wireless networks enable communication between devices using a single technology, 5G networks will need to support seamless connectivity between heterogeneous wireless objects, and consequently enable the proliferation of IoE networks. To tackle the complexity and versatility of the future IoE networks, 5G has to guarantee optimal usage of both spectrum and energy resources and further support technology-agnostic connectivity between objects. This can be realized by combining intelligent network control with adaptive software-defined air interfaces. In order to achieve this, current radio technology paradigms like Cloud RAN and Software Defined Radio (SDR) utilize centralized baseband signal processing mainly performed in software. With traditional SDR platforms, composed of separate radio and host commodity computer units, computationally-intensive signal processing algorithms and high-throughput connectivity between processing units are hard to realize. In addition, significant power consumption and large form factor may preclude any real-life deployment of such systems. On the other hand, modern hybrid FPGA technology tightly couples a FPGA fabric with hard core CPU on a single chip. This provides opportunities for implementing air interfaces based on hardware/software co-processing, resulting in increased processing throughput, reduced form factor and power consumption, while at the same time preserving flexibility. This paper examines how hybrid FPGAs can be combined with novel ideas such as RF Network-on-Chip (RFNoC) and partial reconfiguration, to form a flexible and compact platform for implementing low-power adaptive air interfaces. The proposed platform merges software and hardware processing units of SDR systems on a single chip. Therefore, it can provide interfaces for on-the-fly composition and reconfiguration of software and hardware radio modules. The resulting system enables the abstraction of air interfaces, where each access technology is composed of a structured sequence of modular radio processing units.
Suppliers of Colour TV Trainer Kit, Mobile Phone Trainer Kit, AM/ FM Radio Trainer Kit, Oscilloscope / Demonstrator Trainer, Microwave Test Bench - Klystron Antenna, Advanced MIC Trainer, Microwave Test Bench - Klystron, Microwave Test Bench - Gunn.
Surf Communication Solutions provides of MoP (Media over Packet) Triple Play (Voice, Video, and Modem/Fax/Data) conversion solutions to communication equipment manufacturers. These solutions are provided in various integration levels: DSP software ; PTMC boards; DSP hardware/software; and PCI boards. http://www.surf-com.com
Design and implementation of sdr based qpsk transceiver using fpgaTarik Kazaz
Software-defined radio (SDR) technology enables
implementation of wireless devices that support multiple air interfaces and modulation formats, which is very important
if consider the proliferation of wireless standards. To enable such functionality SDR is using reconfigurable hardware platform such as Field Programmable Gate Array (FPGA). In this paper, we present design procedure and implementation result of SDR based QPSK modulator on Altera Cyclone IV FPGA. For design and implementation of QPSK modulator we used Altera DSP
Builder Tool combined with Matlab/Simulink, Modelsim and
Quartus II design tools. As reconfigurable hardware platform
we used Altera DE2-115 development and education board with
AD/DA daughter card. Software and Hardware-in-the-loop (HIL)
simulation was conducted before hardware implementation and
verification of designed system. This method of design makes
implementation of SDR based modulators simpler ad faster.
Index Terms—SDR, FPGA, QPSK, DSP Builder, NCO, RRC
Software Defined Radio Engineering course samplerJim Jenkins
This 3-day course is designed for digital signal processing engineers, RF system engineers, and managers who wish to enhance their understanding of this rapidly emerging technology. Most topics include carefully described design analysis, alternative approaches, performance analysis, and references to published research results. Many topics are illustrated by Matlab simulation demos. An extensive bibliography is included.
Design And Simulation of Modulation Schemes used for FPGA Based Software Defi...Sucharita Saha
Design of a BPSK and QPSK digital Modulation scheme and its implementation on FPGAs for universal mobile telecommunications system and SDR applications. The simulation of the system is made in MATLAB Simulink environment and System Generator, a tool used for FPGA design. Hardware Co-Simulation is designed using VHDL a hardware description language targeting a Xilinx FPGA and is verified using MATLAB Simulink. It is then converted to VHDL level using Simulink HDL coder. The design is synthesized and fitted with Xilinx 14.2 ISE Edition software, and downloaded to Spartan 3E (XC3S500E) board.
MaxEye Technologies provides complete DVB test and measurement solutions for testing the broadcast equpiments and receivers during manufacturing, design labs and automating the tests. The supported DVB Standards are DVB-T/T2/H, DVB-S/S2, DVB-C, ISDB-T/Tb, ATSC, ATSC-M/H, DAB/DAB Plus/T-DMB, DRM and DRM Plus. In addition to the digital standards we also support AM, FM and RDS. For more information contact ramesh@maxeyetech.com
This document describes the measurement configurations and procedures for DAB receiver testing using National Instruments PXI Vector Signal Generators and MaxEye DAB/DABPlus/T-DMB Signal Generation software.
Only End to End Infotainment Test Solution available in market for Broadcast, Navigation, Connectivity, Cellular Standards, Audio, Video and HMI Testing.
Automotive infotainment system is growing rapidly because of the advancement in technology. More and more new technologies and devices are integrated into the system. Connected automotive infotainment is becoming a must have feature for car manufacturers.
Engineers in the automotive industry face new challenges with infotainment systems, which now introduce additional I/O like audio, video, and RF signals into systems that already have other sensor measurements. MaxEye In-Vehicle Infotainment test solution is powered by National Instruments PXI Platform, Universal Radio Signal Generation Software and LabVIEW Add-on toolkits. NI PXI platform combined with powerful software toolkits and APIs enable engineers to perform complicated tests on the many different I/O types at the same time using one chassis.
MaxEye Technologies is a Bangalore based company with strong expertise in developing test and measurement solutions for infotainment test system. We are an Alliance Partner of National Instruments. MaxEye Technologies provides complete in-car infotainment test solution using NI PXI hardware, Software and MaxEye DVB toolkits.
Our infotainment test solutions are proven and already used by leading CAR manufacturers.
MaxEye Technologies is a Bangalore based company with strong expertise in developing test and measurement solutions for infotainment test system. We are an Alliance Partner of National Instruments. MaxEye Technologies provides complete in-car infotainment test solution using NI PXI hardware, Software and MaxEye DVB toolkits.
Our infotainment test solutions are proven and already used by leading CAR manufacturers.
Rebaca is niche software provider for Video and Telecommunication Industry providing strategic solutions to OEM’s , Appliance vendors and Device manufacturers. Rebaca’s extensive portfolio of services and solutions covers Video Delivery , Streaming , Mobile Video Applications, Digital TV, Telecom Middleware, Policy Server , DPI , Element Management System,Communication and Multimedia Applications.
Specialization in offering the world class range of Communication Devices that are sourced from the most reliable vendors in the market. The diversified range includes Multimeter, Optical Test Equipment, Under Ground Utility Locator, Fiber Optic Passive Components, LCD Display, RF Test Equipment, Fusion Splicing Machine and Accessories and various others.
NavikEye is the Multiconstellation GNSS simulator from MaxEye Technologies.
NavikEye Multi-constellation GNSS Simulator offers realtime generation of various global satellite navigation signals including dynamic scenarios and HIL simulation. The scenario generation can be fully automated using the remote TCP commands via Ethernet. This enables the implementation of dynamic HIL environment. The HIL test system can feed the realtime location coordinates, velocity and other vehicle dynamics to the GNSS Simulator. Based on this GNSS simulator updates the receiver position in realtime.
The simulator supports moving receiver scenarios with predefined waypoints using NMEA and KML files. NavikEye GNSS Simulator is based on National Instruments scalable and software defined PXI architecture powered by LabVIEW.
MaxEye Technologies offers comprehensive telematics test solution for automotive vehicles. Our Telematics and Infotainment Test solution is based on scalable and software defined PXI architecture powered by LabVIEW and TestStand test automation software. The test system emulates the connected car environment, virtual driving, vehicle parameters using CAN simulation, simulated hardware I/O and communication with the web server.
MaxEye Technologies pleased to announce the release of new RF test and measurement product for IOT devices testing, Z-Wave Measurement Suite.
Z-Wave is a low-power, low-cost wireless technology enabling consumer-grade products with networked features. Z-Wave is based on ITU-T G.9959 standard. Z-Wave operates in the industrial, scientific and medical (ISM) radio bands: It uses 868.42 MHz in Europe and 908.42MHz in USA. The Physical Layer and RF front end of the Z-Wave devices needs to be tested comprehensively to meet the requirements of the ITU-T G.9959 standard. The familiarity of the standard is very important to start preparing to test the Physical layer of the Z-Wave devices.
MaxEye Technologies provides the signal generation and analysis tools using National Instruments Vector Signal Generators/Analyzers or Vector Signal Transceiver to test the physical layer and RF front end of the Z-Wave devices.
For more information: http://maxeyetech.com/zwavemeasurementsuite.php
MaxEye Technologies provides complete STB test solution using National Instruments PXI hardware and MaxEye Software. The complete solution is developed using single PXI instrument.
Let's dive deeper into the world of ODC! Ricardo Alves (OutSystems) will join us to tell all about the new Data Fabric. After that, Sezen de Bruijn (OutSystems) will get into the details on how to best design a sturdy architecture within ODC.
Accelerate your Kubernetes clusters with Varnish CachingThijs Feryn
A presentation about the usage and availability of Varnish on Kubernetes. This talk explores the capabilities of Varnish caching and shows how to use the Varnish Helm chart to deploy it to Kubernetes.
This presentation was delivered at K8SUG Singapore. See https://feryn.eu/presentations/accelerate-your-kubernetes-clusters-with-varnish-caching-k8sug-singapore-28-2024 for more details.
State of ICS and IoT Cyber Threat Landscape Report 2024 previewPrayukth K V
The IoT and OT threat landscape report has been prepared by the Threat Research Team at Sectrio using data from Sectrio, cyber threat intelligence farming facilities spread across over 85 cities around the world. In addition, Sectrio also runs AI-based advanced threat and payload engagement facilities that serve as sinks to attract and engage sophisticated threat actors, and newer malware including new variants and latent threats that are at an earlier stage of development.
The latest edition of the OT/ICS and IoT security Threat Landscape Report 2024 also covers:
State of global ICS asset and network exposure
Sectoral targets and attacks as well as the cost of ransom
Global APT activity, AI usage, actor and tactic profiles, and implications
Rise in volumes of AI-powered cyberattacks
Major cyber events in 2024
Malware and malicious payload trends
Cyberattack types and targets
Vulnerability exploit attempts on CVEs
Attacks on counties – USA
Expansion of bot farms – how, where, and why
In-depth analysis of the cyber threat landscape across North America, South America, Europe, APAC, and the Middle East
Why are attacks on smart factories rising?
Cyber risk predictions
Axis of attacks – Europe
Systemic attacks in the Middle East
Download the full report from here:
https://sectrio.com/resources/ot-threat-landscape-reports/sectrio-releases-ot-ics-and-iot-security-threat-landscape-report-2024/
Slack (or Teams) Automation for Bonterra Impact Management (fka Social Soluti...Jeffrey Haguewood
Sidekick Solutions uses Bonterra Impact Management (fka Social Solutions Apricot) and automation solutions to integrate data for business workflows.
We believe integration and automation are essential to user experience and the promise of efficient work through technology. Automation is the critical ingredient to realizing that full vision. We develop integration products and services for Bonterra Case Management software to support the deployment of automations for a variety of use cases.
This video focuses on the notifications, alerts, and approval requests using Slack for Bonterra Impact Management. The solutions covered in this webinar can also be deployed for Microsoft Teams.
Interested in deploying notification automations for Bonterra Impact Management? Contact us at sales@sidekicksolutionsllc.com to discuss next steps.
GraphRAG is All You need? LLM & Knowledge GraphGuy Korland
Guy Korland, CEO and Co-founder of FalkorDB, will review two articles on the integration of language models with knowledge graphs.
1. Unifying Large Language Models and Knowledge Graphs: A Roadmap.
https://arxiv.org/abs/2306.08302
2. Microsoft Research's GraphRAG paper and a review paper on various uses of knowledge graphs:
https://www.microsoft.com/en-us/research/blog/graphrag-unlocking-llm-discovery-on-narrative-private-data/
Search and Society: Reimagining Information Access for Radical FuturesBhaskar Mitra
The field of Information retrieval (IR) is currently undergoing a transformative shift, at least partly due to the emerging applications of generative AI to information access. In this talk, we will deliberate on the sociotechnical implications of generative AI for information access. We will argue that there is both a critical necessity and an exciting opportunity for the IR community to re-center our research agendas on societal needs while dismantling the artificial separation between the work on fairness, accountability, transparency, and ethics in IR and the rest of IR research. Instead of adopting a reactionary strategy of trying to mitigate potential social harms from emerging technologies, the community should aim to proactively set the research agenda for the kinds of systems we should build inspired by diverse explicitly stated sociotechnical imaginaries. The sociotechnical imaginaries that underpin the design and development of information access technologies needs to be explicitly articulated, and we need to develop theories of change in context of these diverse perspectives. Our guiding future imaginaries must be informed by other academic fields, such as democratic theory and critical theory, and should be co-developed with social science scholars, legal scholars, civil rights and social justice activists, and artists, among others.
GDG Cloud Southlake #33: Boule & Rebala: Effective AppSec in SDLC using Deplo...James Anderson
Effective Application Security in Software Delivery lifecycle using Deployment Firewall and DBOM
The modern software delivery process (or the CI/CD process) includes many tools, distributed teams, open-source code, and cloud platforms. Constant focus on speed to release software to market, along with the traditional slow and manual security checks has caused gaps in continuous security as an important piece in the software supply chain. Today organizations feel more susceptible to external and internal cyber threats due to the vast attack surface in their applications supply chain and the lack of end-to-end governance and risk management.
The software team must secure its software delivery process to avoid vulnerability and security breaches. This needs to be achieved with existing tool chains and without extensive rework of the delivery processes. This talk will present strategies and techniques for providing visibility into the true risk of the existing vulnerabilities, preventing the introduction of security issues in the software, resolving vulnerabilities in production environments quickly, and capturing the deployment bill of materials (DBOM).
Speakers:
Bob Boule
Robert Boule is a technology enthusiast with PASSION for technology and making things work along with a knack for helping others understand how things work. He comes with around 20 years of solution engineering experience in application security, software continuous delivery, and SaaS platforms. He is known for his dynamic presentations in CI/CD and application security integrated in software delivery lifecycle.
Gopinath Rebala
Gopinath Rebala is the CTO of OpsMx, where he has overall responsibility for the machine learning and data processing architectures for Secure Software Delivery. Gopi also has a strong connection with our customers, leading design and architecture for strategic implementations. Gopi is a frequent speaker and well-known leader in continuous delivery and integrating security into software delivery.
Essentials of Automations: Optimizing FME Workflows with ParametersSafe Software
Are you looking to streamline your workflows and boost your projects’ efficiency? Do you find yourself searching for ways to add flexibility and control over your FME workflows? If so, you’re in the right place.
Join us for an insightful dive into the world of FME parameters, a critical element in optimizing workflow efficiency. This webinar marks the beginning of our three-part “Essentials of Automation” series. This first webinar is designed to equip you with the knowledge and skills to utilize parameters effectively: enhancing the flexibility, maintainability, and user control of your FME projects.
Here’s what you’ll gain:
- Essentials of FME Parameters: Understand the pivotal role of parameters, including Reader/Writer, Transformer, User, and FME Flow categories. Discover how they are the key to unlocking automation and optimization within your workflows.
- Practical Applications in FME Form: Delve into key user parameter types including choice, connections, and file URLs. Allow users to control how a workflow runs, making your workflows more reusable. Learn to import values and deliver the best user experience for your workflows while enhancing accuracy.
- Optimization Strategies in FME Flow: Explore the creation and strategic deployment of parameters in FME Flow, including the use of deployment and geometry parameters, to maximize workflow efficiency.
- Pro Tips for Success: Gain insights on parameterizing connections and leveraging new features like Conditional Visibility for clarity and simplicity.
We’ll wrap up with a glimpse into future webinars, followed by a Q&A session to address your specific questions surrounding this topic.
Don’t miss this opportunity to elevate your FME expertise and drive your projects to new heights of efficiency.
Builder.ai Founder Sachin Dev Duggal's Strategic Approach to Create an Innova...Ramesh Iyer
In today's fast-changing business world, Companies that adapt and embrace new ideas often need help to keep up with the competition. However, fostering a culture of innovation takes much work. It takes vision, leadership and willingness to take risks in the right proportion. Sachin Dev Duggal, co-founder of Builder.ai, has perfected the art of this balance, creating a company culture where creativity and growth are nurtured at each stage.
PHP Frameworks: I want to break free (IPC Berlin 2024)Ralf Eggert
In this presentation, we examine the challenges and limitations of relying too heavily on PHP frameworks in web development. We discuss the history of PHP and its frameworks to understand how this dependence has evolved. The focus will be on providing concrete tips and strategies to reduce reliance on these frameworks, based on real-world examples and practical considerations. The goal is to equip developers with the skills and knowledge to create more flexible and future-proof web applications. We'll explore the importance of maintaining autonomy in a rapidly changing tech landscape and how to make informed decisions in PHP development.
This talk is aimed at encouraging a more independent approach to using PHP frameworks, moving towards a more flexible and future-proof approach to PHP development.
LF Energy Webinar: Electrical Grid Modelling and Simulation Through PowSyBl -...DanBrown980551
Do you want to learn how to model and simulate an electrical network from scratch in under an hour?
Then welcome to this PowSyBl workshop, hosted by Rte, the French Transmission System Operator (TSO)!
During the webinar, you will discover the PowSyBl ecosystem as well as handle and study an electrical network through an interactive Python notebook.
PowSyBl is an open source project hosted by LF Energy, which offers a comprehensive set of features for electrical grid modelling and simulation. Among other advanced features, PowSyBl provides:
- A fully editable and extendable library for grid component modelling;
- Visualization tools to display your network;
- Grid simulation tools, such as power flows, security analyses (with or without remedial actions) and sensitivity analyses;
The framework is mostly written in Java, with a Python binding so that Python developers can access PowSyBl functionalities as well.
What you will learn during the webinar:
- For beginners: discover PowSyBl's functionalities through a quick general presentation and the notebook, without needing any expert coding skills;
- For advanced developers: master the skills to efficiently apply PowSyBl functionalities to your real-world scenarios.
2. About MaxEye Technologies
MaxEye Technologies, founded in 2011, is a privately held company based in Bangalore,
India, Alliance Partner of National Instruments. We specialize in providing products,
services and turnkey solutions in signal processing and communication systems.
Your One-Stop Provider for
Design and development of complete wireless receivers, transmitters and
physical layer IPs.
Complete system development for RF test and measurement applications.
LabVIEW and Matlab simulations for Research and Prototype development.
Channel modelling to simulate real time conditions including antenna and
atmospheric models.
Complete end to end product development services using in house developed
software and third party hardware.
Porting the software in DSP and FPGA platforms.
Our Products
Digital Video RF Test and Measurement
MaxEye Technologies provides comprehensive solution in digital video and audio
broadcast test. We provide generation and analysis functions in NI LabVIEW system
design software, for generating and analyzing the standard complaint signals for the
following Digital Video/Audio Broadcasting (DVB/DAB) standards
ISDB-T+
DAB/DAB Plus+
DVB-T2+
ISDB-Tb+
DRM/DRM Plus+
DVB-S+
CMMB+
ATSC-M/H
DVB-S2+
DTMB
T-DMB+
+
DVB-T/H+
DVB-C+
ATSC
At present, analysis functions are supported only for these standards.
3. The MaxEye Signal Generation Software is an ideal test tool for generating test
signals with different configurations and under different conditions. It can be used to
completely test the receiver to characterize its performance during design, verification
and manufacturing. Our software is capable of supporting multiple payload types –
MPEG TS, Audio files, Test Patterns, User Defined Bits, Binary files and PN Sequence.
Coding, modulation and other parameters of the toolkit can be easily configured using
the LabVIEW API VI’s that are provided with our software, to generate custom
waveform for specific test requirements. The toolkit also supports adding impairments
like AWGN, IQ impairments, frequency and clock offsets to stress the receiver under real
world conditions. The receiver’s performance can be verified through BER analysis at
various stages (e.g. BER after demodulation, BER after inner decoding and BER after
outer decoding).
MaxEye Signal Generation Software
NI PXI RF Platform
4. The MaxEye Digital Video Analysis toolkit is an ideal tool for analyzing the
signal quality of the transmitted signal. The toolkit measurements can be used to
calibrate the Digital Video Transmitter components. It provides standards-based
modulation accuracy, power measurements and spectral measurements to help
engineers evaluate, design and manufacture transmitters, amplifiers, tuners, repeaters,
modulators and gap-fillers. Coding, modulation and other parameters of the toolkit can
be easily configured using the LabVIEW API VI’’s that are provided with our software to
analyze custom waveform for specific test requirements.
MaxEye Signal Analysis Software
MaxEye analysis toolkit provides various measurement traces to enable the engineers
to analyze, troubleshoot and validate the transmitter signal issues. The toolkit
measurements can be used to calibrate the DVB transmitter. The EVM vs Subcarriers
and EVM vs Symbols enable the time and frequency domain analysis of the transmitted
signal to identify the issues in the transmitted signal. The channel frequency response
trace gives the spectral flatness of the RF Front end.
5. Key Features of the MaxEye Digital Video and Audio Broadcasting Toolkits
Features
DVB-S
DVB-S2
DVB-T/H
DVB-T2
DVB-C
ISDBT/Tb
Real-time signal
generation
Multi Carrier Signal
Generation
Bandwidth
Configura
ble
Configura
ble
5,6,7 and
8 MHz
Coding
RS+CC
RS+CC
Modulation
Single
Carrier
BCH+
LDPC
Single
Carrier
Modulation
Schemes
QPSK
QPSK,
8PSK,
16APSK,
32APSK
Impairments
AWGN,
IQ,
Frequenc
y and
Clock
offset
MPEG TS,
PN
Sequence,
User
Defined
Bits
Payload Types
Programming
Examples
LabVIEW API VIs
Creation of Signalling
Parameters
OFDM Windowing
Modulation Analysis
(EVM,
MER,
Frequency Offset,
Clock Offset,
Decoding of
Signalling
Parameters,
Constellation Graph,
Channel Frequency
Response,
EVM Vs Subcarriers,
EVM Vs Symbols,
MER Vs Subcarriers,
MER Vs Symbols )
IQ Impairment
Measurements
(Gain Imbalance,
Quadrature Skew,
IQ Offset)
Spectral
Measurements
(ACLR,
Channel Power,
Spectral Emission
Mask)
Supported Hardware
ATSC and
ATSC-M/H
DTMB
CMMB
DAB/DA
B Plus/
T-DMB
DRM/
DRM
Plus
1.7, 5, 6, 7,
8 and 10
MHz
Configura
ble
6.7 and 8
MHZ
1.536
MHz
6 MHz
8 MHz
2 and 8
MHz
4.5, 5 ,9
,10, 18 20
KHz
BCH+
LDPC
OFDM
RS
RS+CC
RS+CC
RS+SCCC
OFDM
OFDM
VSB
RS+
LDPC
OFDM
CC
Single
Carrier
QPSK,
16QAM
64QAM
QPSK,
16QAM
64QAM
256QAM
16QAM
32QAM
64QAM
128 QAM
256QAM
QPSK,
16QAM
64QAM
QPSK
8-VSB
BPSK,
QPSK,
16QAM
QPSK,
16QAM
64QAM
AWGN,
IQ,
Frequenc
y and
Clock
offset
MPEG TS,
PN
Sequence,
User
Defined
Bits
AWGN,
IQ,
Frequenc
y and
Clock
offset
MPEG TS,
PN
Sequence,
User
Defined
Bits
AWGN, IQ,
Frequency
and Clock
offset
AWGN, IQ,
Frequency
and Clock
offset
MPEG TS,
PN
Sequence,
User
Defined
Bits
AWGN,
IQ,
Frequenc
y and
Clock
offset
MPEG TS,
PN
Sequence,
User
Defined
Bits
AWGN, IQ,
Frequency
and Clock
offset
MPEG TS,
PN
Sequence,
User
Defined
Bits
AWGN,
IQ,
Frequenc
y and
Clock
offset
MPEG TS,
PN
Sequence,
User
Defined
Bits
MPEG TS,
PN
Sequence,
User
Defined
Bits
BCH+
LDPC
Single
Carrier
and
OFDM
4QAM,
4QAMNR,
16QAM,
32QAM,
64QAM
AWGN,
IQ,
Frequenc
y and
Clock
offset
MPEG TS,
PN
Sequence,
User
Defined
Bits
AWGN,
IQ,
Frequenc
y and
Clock
offset
MFS File,
PN
Sequence,
User
Defined
Bits
AWGN,
IQ,
Frequenc
y and
Clock
offset
MPEG TS,
PN
Sequence,
User
Defined
Bits
NI
VSG/VSA,
NI VST,
NI USRP
NI
VSG/VSA,
NI VST,
NI USRP
NI
VSG/VSA,
NI VST,
NI USRP
NI
VSG/VSA,
NI VST,
NI USRP
NI
VSG/VSA,
NI VST,
NI USRP
NI
VSG/VSA,
NI VST,
NI USRP
NI
VSG/VSA,
NI VST,
NI USRP
NI
VSG/VSA,
NI VST,
NI USRP
NI
VSG/VSA,
NI VST,
NI USRP
NI
VSG/VSA,
NI VST,
NI USRP
NI
VSG/VSA,
NI VST,
NI USRP
OFDM
OFDM
6. DVB Test Applications
Your One Stop Provider for all Digital Video and Audio Broadcasting Test Requirements
Set-Top Box Testing
Vehicle Infotainment Testing
Digital TV (DTV) Tuner Testing
Mobile TV Tuner Testing
Digital Video and Audio Broadcast Equipment Testing
MaxEye Single Carrier QPSK Transmitter and Receiver
Configurable Symbol Rates (Depending on the Hardware specifications)
Code Rates: ½, 2/3, ¾, 5/6 and 7/8
FEC : RS + Convolutional Code or BCH + LDPC (Supported both combinations)
Implemented in Verilog for FPGA Platform
Complete C source code or Verilog RTL IP available
Can easily customized for specific requirement
For Satellite, Telemetry, Wireless Backhaul and other line of sight applications
Our Software IP Core Modules
3GPP Spatial Channel Model (LabVIEW)
LDPC Encoder and Decoder ( C, LabVIEW and Verilog IP)
RS Encoder and Decoder ( C, LabVIEW and Verilog IP)
Convolutional Encoder and Viterbi Decoder ( C, LabVIEW and Verilog IP)
Turbo Encoder and Decoder (C)
QPSK Modulator and Demodulator ( C, LabVIEW and Verilog IP)
Fractional Resampler (C, LabVIER and Verilog/VHDL IP)
7. Our Product Advantage
Our test and measurement solutions are at the forefront of broadcast technology.
When programmed with LabVIEW and paired with different NI PXI RF hardware
instrumentation (NI RFSG, NI RFSA and the NI Vector Signal Transceiver),
MaxEye DVB toolkits can help engineers create a complete, customized test
solution for testing various DVB transmitters and receivers.
It can also be used to characterize the performance of DTV tuners, broadcast
equipment, power amplifiers, and more.
Engineers can quickly take measurements using the programming examples
provided with the toolkits or build fully automated applications using the
LabVIEW API VIs that come with our toolkit software.
Our toolkits enable real-time streaming of the generated waveform using the NI
RFSG streaming mode.
Customers are currently using our products for testing their DVB devices and we
are constantly improving the quality of our products.
MaxEye Products in NI LabVIEW Tools Network
MaxEye Digital Video and Audio RF test and measurement toolkits are also available for
purchase from National Instruments LabVIEW Tools Network. Our Products are
compatile with LabVIEW certification and are also distributed through the LabVIEW
tools Network. Please see the National Instruments website link below for more
information.
http://www.ni.com/np/app/main/p/bot/no/ap/lvtn/lang/en/pg/1/sn/n25:software,
n21:28/sb/default/?q=MaxEye.
Customer Feedback
“It was simple to configure and generate the DVB-T signal, and we identified errors very
easily through good error handling,” said the DTV testing group at Tata Consultancy
Services in Bangalore, India. “Last but not least, good support from MaxEye
Technologies helped us complete the project on time.”
8. About the LabVIEW Tools Network
NI Alliance Partners accelerate developer productivity by creating LabVIEW software
add-ons and apps that receive a Compatible with LabVIEW certification and are
distributed through the LabVIEW Tools Network.
For more information visit http://www.ni.com/labviewtools/.
Support and Software Maintenance
MaxEye has a test and measurement solution for you if you are working with terrestrial
TV, mobile TV, cable TV, satellite TV, or any other broadcast audio standards. We offer
cost effective software maintenance and support for your application development and
automated test environment with free software upgrade for all the supported features
of the toolkits. We offer technical support through our talented engineers who are
domain experts in digital video broadcasting test solutions and other signal processing
and communication software. For more details about our support program please
contact us at info@maxeyetech.com.
www.maxeyetech.com
9. The name "MaxEye" comes from Communication Engineering. Our logo
symbolizes the Eye Diagram. The Eye Diagram is a Signal display pattern in
which the digital signal in the receiver is repetitively sampled. The signal is
plotted every symbol period or multiples of the same. The pattern is so
called because it appears like a series of eyes between two parallel rails.
This pattern is usually used to diagnose the timing synchronization in a
digital receiver. An open eye pattern corresponds to minimal signal
distortion or in other words can conclude a near perfect time
synchronization. A clear open eye pattern is also called "MaxEye".
Corporate Headquarters
MaxEye Technologies Pvt. Ltd.
#124, 3rd Floor, 'A' Cross,
Nanja Reddy Colony, Murugeshpalya,
Bangalore - 560 017
Karnataka
India.
Phone: +91-80-2527 0024
E-mail: info@maxeyetech.com
ramesh@maxeyetech.com
Website: www.maxeyetech.com