Solutions

Our Infrastructure IT Solutions

We offer cutting-edge specialization in state-of-the-art Infrastructure IT Solutions

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Graphics and Game Development Center Setup

The Graphics and Game Development Center aims to foster creativity, skill-building, and collaboration among…

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AI Development Lab Setup

The AI Development Lab aims to create an environment where researchers, developers, and enthusiasts can explore…

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Integrated CNS and ATC System Using Multicasting

The Integrated CNS and ATC System leverages advanced technologies to transform air traffic management. By…

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Datacentre and Campus Network Setup

The Datacenter and Campus Network Setup project focuses on creating reliable, scalable, and interconnected networks…

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Campus Wireless Solution

Summery – We offer state-of-the-art solutions for campus wireless networks. These solutions are meticulously designed to…

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Voice over IP/Packet Solutions

Summery – We have designed and implemented state-of-the-art VoP solutions through VoIP processors and modules…

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Video Conferencing Solutions

Video conferencing solutions play a crucial role in government agencies, especially as remote work and collaboration become…

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Graphics and Game Development Center Setup

Graphics and Game Development Center Setup

Overview

The Graphics and Game Development Center aims to foster creativity, skill-building, and collaboration among enthusiasts, students, and professionals interested in game design, 3D modeling, animation, and interactive media. Whether you’re an indie developer, educator, or hobbyist, this center provides a dynamic space for exploration and learning.

Key Phases

Pre-Production:
  • Planning: Define the center’s goals, target audience, and available resources.
  • Infrastructure: Set up physical space—ergonomic workstations, monitors, and comfortable seating.
  • Software: Install essential tools—game engines (e.g., Unity, Unreal Engine), 3D modeling software (e.g., Blender), and version control systems (e.g., Git).
Production:
  • Workshops and Training: Organize workshops on game development, character design, texturing, and animation.
  • Collaboration: Encourage interdisciplinary collaboration—artists, programmers, sound designers, and writers working together.
  • Project Development: Initiate game projects—2D/3D games, interactive experiences, or virtual reality content.
Post-Production:
  • Testing and Iteration: Test games on various platforms (PC, consoles, mobile) and gather feedback.
  • Showcase Events: Host game showcases, demo days, and portfolio reviews.
  • Community Engagement: Connect with local game development communities, attend conferences, and invite guest speakers.

Resources

  • Hardware: High-performance PCs with powerful CPUs and GPUs, SSDs, and quality monitors.
  • Software: Game engines (Unity, Unreal Engine), 3D modeling tools (Blender, Maya), audio editing software (Audacity), and version control (Git).
  • Networking: Stable internet for online collaboration and updates.
  • Educational Materials: Books, tutorials, and online courses.

AI Development Lab Setup

Overview

The AI Development Lab aims to create an environment where researchers, developers, and enthusiasts can explore artificial intelligence (AI), machine learning (ML), and data science. Whether you’re building AI models, experimenting with neural networks, or diving into natural language processing, this lab provides the infrastructure and resources needed for groundbreaking work.

Key Phases

Infrastructure Setup:
  • Hardware: workstations or servers equipped with GPUs (NVIDIA or AMD) for accelerated training.
  • Data Storage: Set up robust storage solutions for datasets—SSDs or network-attached storage (NAS).
Data Preparation and Exploration:
  • Data Pipelines: Create pipelines for data ingestion, preprocessing, and augmentation.
  • Exploratory Data Analysis (EDA): Use tools like Pandas and Matplotlib to understand your data.
Model Development and Training:
  • Experiment Tracking: Implement tools (e.g., MLflow, TensorBoard) to monitor experiments and model performance.
  • Hyperparameter Tuning: Optimize model hyperparameters for better results.
  • GPU Utilization: Maximize GPU utilization during training.
Deployment and Monitoring:
  • Model Deployment: Deploy models as APIs (using Flask, FastAPI, or Docker) for real-world use.
  • Monitoring and Alerts: Set up monitoring to track model performance, drift, and anomalies.

Resources

  • Talent: Recruit data scientists, ML engineers, and domain experts.
  • Training Materials: Provide access to online courses, tutorials, and research papers.
  • Collaboration Spaces: Foster knowledge sharing and teamwork.

Integrated CNS and ATC System Using Multicasting

Overview

The Integrated CNS and ATC System leverages advanced technologies to transform air traffic management. By combining Communication, Navigation, and Surveillance (CNS) capabilities with efficient multicast communication, this project aims to achieve seamless coordination, real-time data sharing, and improved safety across the aviation domain.

Key Objectives

Multicasting for Data Dissemination:
  • Implement multicast communication protocols to efficiently distribute critical information (e.g., weather updates, flight plans, radar data) to multiple recipients simultaneously.
  • Reduce network congestion and latency by using multicast groups for targeted data delivery.
Enhanced Surveillance:
  • Integrate radar, ADS-B (Automatic Dependent Surveillance-Broadcast), and satellite-based surveillance systems.
  • Enable real-time aircraft tracking, conflict detection, and resolution.
Collaborative Decision-Making:
  • Facilitate seamless communication between ATC centers, airlines, and pilots.
  • Enable collaborative decision-making for route optimization, weather diversions, and airspace management.
Interoperability and Harmonization:
  • Ensure compatibility with existing CNS/ATC systems worldwide.
  • Harmonize standards and procedures to promote global interoperability.

Benefits

  • Safety: Enhanced situational awareness and timely information sharing lead to safer operations.
  • Efficiency: Multicasting reduces communication overhead, streamlining data dissemination.
  • Capacity: Improved airspace utilization and reduced delays.
  • Environmental Impact: Optimal routing minimizes fuel consumption and emissions.

Conclusion

The Integrated CNS and ATC System Using Multicasting represents a leap forward in aviation technology. By fostering collaboration, innovation, and harmonization, this project contributes to a safer and more efficient global airspace.

Datacentre and Campus Network Setup

Overview

The Datacenter and Campus Network Setup project focuses on creating reliable, scalable, and interconnected networks to support critical business operations. It encompasses two key areas:

Datacenter Network:

Purpose: The datacenter serves as the heart of an organization’s IT infrastructure, hosting servers, storage, and applications.

Design Considerations:

  • High Availability: Implement redundancy, failover mechanisms, and load balancing for uninterrupted service.
  • Scalability: Design for growth, accommodating additional servers and storage as needed.
  • Security: Deploy firewalls, intrusion detection/prevention systems, and access controls.
  • Network Segmentation: Isolate different services (e.g., web servers, databases) using VLANs or microsegmentation.
Campus Network:

Scope: The campus network covers office buildings, educational institutions, or any geographically localized area.

Design Goals:

  • Coverage: Ensure seamless connectivity across all campus buildings.
  • Scalability: Plan for future growth and changing user needs.
  • Quality of Service (QoS): Prioritize critical applications (voice, video) over less time-sensitive traffic.
  • Security: Implement network access controls, intrusion prevention, and user authentication.
  • Redundancy: Design redundant paths to prevent single points of failure.

Benefits

  • Efficiency: Streamlined datacenter operations and optimized campus connectivity.
  • Reliability: Resilient networks with minimal downtime.
  • Security: Safeguarded data and applications.
  • Scalability: Ready for organizational growth.
  • Integration: Ensuring seamless communication between datacenters and campus networks.

Conclusion

The Datacenter and Campus Network Setup project lays the foundation for efficient communication, collaboration, and productivity. By addressing both datacenter and campus needs, organizations can thrive in today’s interconnected world.

Campus Wireless Solution

Campus Wireless Solution

Summery – We offer state-of-the-art solutions for campus wireless networks. These solutions are meticulously designed to provide seamless connectivity, robust security, and scalability.

Description

Campus LAN and Wireless LAN Integration:
  • Our approach integrates both wired LAN (Local Area Network) and wireless LAN to create a comprehensive network access solution. This means that whether you’re connecting via an Ethernet cable or wirelessly, our infrastructure ensures a consistent experience.
  • The wired LAN serves as the foundation, providing high-speed connectivity to various endpoints across the campus. Meanwhile, the wireless LAN extends this connectivity to mobile devices, laptops, and other wireless clients.
  • We understand that today’s campus users demand ubiquitous access, whether they’re in lecture halls, libraries, dorms, or outdoor spaces. Our design caters to these diverse requirements.
Resilience and Always-On Connectivity:
  • Our network architecture prioritizes resilience. Just like a well-engineered plumbing system in a large stadium or high-rise building, our network is designed to handle peak loads, protect against tampering, and ensure continuous operation.
  • Users rely on the network for critical tasks, from accessing essential information to making voice or video calls. Therefore, our infrastructure is always on and available.
Intelligence Beyond Basics:
  • We go beyond basic networking standards. Our solutions adapt to changing needs, leveraging insights into network activity. This intelligence allows us to optimize performance, troubleshoot efficiently, and enhance user experiences.
  • As technology evolves, we stay ahead of the curve. For instance, we’re ready for Wi-Fi 6 (802.11ax) technology, which offers speeds exceeding 1 Gbps. We also support the 802.3bz standard, defining 2.5 Gbps and 5 Gbps Ethernet, without requiring an upgrade of existing copper Ethernet wiring.
Power Over Ethernet (PoE):
  • Our design accommodates devices with higher power requirements. Lighting, surveillance cameras, virtual desktop terminals, and access points all need power. We ensure that PoE (Power over Ethernet) can deliver up to 90W per port.
  • During switch upgrades or reboots, our access layer switches provide perpetual PoE, ensuring uninterrupted service.
Security and Compliance:
  • Compliance matters. We choose platforms that align with standards certifications and security protocols like MACsec.
  • Additionally, we enable analytics using technologies such as NetFlow, allowing you to monitor and analyze network traffic effectively.
IoT-Ready Infrastructure:
  • The Internet of Things (IoT) is transforming campuses. Our network supports IoT devices, and we implement segmentation and virtualization technologies. Cisco’s Software-Defined Access (SD-Access) allows for scalability and policy-driven network management.
Voice over IP/Packet Solutions

Voice over IP/Packet Solutions

Summery – We have designed and implemented state-of-the-art VoP solutions through VoIP processors and modules.

Descriptions

VoIP Processors and Modules:
  • We have collaborated with technology providers to offer VoIP processors and modules. These components are essential for building voice communication solutions.
  • VoIP processors are integrated circuits (ICs) designed specifically for handling voice traffic in packet networks. They perform tasks like encoding and decoding voice signals, echo cancellation, and handling various voice codecs.
  • These processors are suitable for various applications, including high-density VoIP gateways, residential gateways, integrated access devices (IADs), small gateways, analog telephony adapters (ATAs), and IP phones.
Key features of VoIP
  • Voice Coders: Support for various voice codecs like G.711, G.729, GSM FR/EFR, AMR, and more.
  • Echo Cancellation: State-of-the-art echo cancellation algorithms to improve call quality.
  • Quality Enhancements: Features like voice activity detection (VAD), comfort noise generation (CNG), and packet loss concealment (PLC).
  • Signaling: Inband and out-of-band signaling, caller ID detection, and more.
  • Security: Support for secure Real-Time Transport Protocol (SRTP) and encryption.
  • Packetization: Handling RTP/RTCP and DTMF relay.

These processors allow OEMs to build high-quality, reliable VoIP products and solutions.

Video Conferencing Solutions

Video Conferencing Solutions

Summery – We offer state-of-the-art video conferencing solutions using industry standard OEMs.

Description – Video conferencing solutions play a crucial role in government agencies, especially as remote work and collaboration become more prevalent. Let me provide you with a concise summary of key points related to video conferencing solutions in government company campuses:

Key Points

Cybersecurity Considerations:

Government users rely on video conferencing and other collaboration tools for telework. However, it’s essential to balance convenience and usability with cybersecurity requirements.

The Cybersecurity and Infrastructure Security Agency (CISA) recommends that federal agencies incorporate cybersecurity considerations when adopting or expanding the use of video conferencing software.

Threat vectors include exploiting unpatched vulnerabilities, disrupting operations, and eavesdropping on meetings.

Benefits of Video Conferencing Solutions:
  • Cost Savings: Video conferencing reduces transit costs by enabling virtual meetings among staff in different locations.
  • Accessibility: Remote participation in council meetings becomes possible, making them more inclusive for council members and the public.
  • Clear Audio: Professional-grade sound systems, microphones, and speakers ensure crisp audio during meetings and court proceedings