Large Language Models (LLMs) like GPT-4, Llama-2, Llama-3, Mistral, and Phi have changed how we handle, understand and process language. However, evaluating these models is crucial to make sure they work well and are trustworthy in different applications.

Harnessing the Power of LLM Evaluation with RAGAS: A Comprehensive Guide

Embracing Synthetic Data: The Benefits

Large Language Models (LLMs) like GPT-4, Llama-2, Llama-3, Mistral, and Phi have changed how we handle, understand and process language. However, evaluating these models is crucial to make sure they work well and are trustworthy in different applications. The RAGAS framework is a new and emerging method for evaluating these models. This blog explores how RAGAS works and how it can be used to assess LLMs.


RAGAS, or RAG Assessment, is a framework designed to evaluate Retrieval Augmented Generation (RAG) pipelines and an application that uses Large Language Models (LLMs) enhanced by external data to improve context and relevance. While there are various tools available to build these RAG pipelines, assessing their performance can be challenging. RAGAS addresses this challenge by providing a suite of tools based on the latest research, enabling users to evaluate and quantify the effectiveness of LLM-generated text within their pipelines.


RAGAS not only helps in assessing the quality of the output but can also be integrated into Continuous Integration and Continuous Deployment (CI/CD) workflows, allowing for continuous monitoring and performance checks. This integration ensures that the RAG pipeline maintains its quality and effectiveness over time, providing valuable insights and helping to optimize the system’s performance.

RAGAS Evaluation Metrics

1. RAGAS Evaluation Metrics
  • The query or prompt provided to the chatbot.
  • Serves as the initial input for the system.
2. Context
  • Relevant text passages extracted from the knowledge base.
  • Provide information to support the answer generation process.
  • Crucial for understanding the chatbot’s ability to retrieve relevant information.
3. Answer
  • The generated response from the chatbot.
  • Reflects the system’s ability to process information from the contexts and questions.
4. Ground Truth Answer
  • The correct or expected response to the question.
  • Serves as the benchmark for evaluating the generated answer’s accuracy.

Components of RAGAS metrics

1. Faithfulness:

This metric evaluates the factual consistency of a generated answer against a given context. It is calculated by comparing the claims made in the answer to those inferable from the context. The score is scaled between 0 and 1, with higher values indicating greater faithfulness.

Calculation

A generated answer is considered faithful if all its claims can be supported by the provided context. To compute the faithfulness score:

  1. Identify claims: Extract a set of claims from the generated answer.
  2. Cross-check: Verify each claim against the context to determine if it can be inferred.
  3. Calculate score: Use the following formula:

Faithfulness score = Number of supported claims / Total number of claims

Example [1],2

Question: Where and when was C.V. Raman born?

Context: C.V. Raman (born 7 November 1888) was an Indian physicist, known for his groundbreaking work on the scattering of light and for the discovery of the Raman effect. 

High faithfulness answer: Raman was born in India on 7th November 1888.  

  • Both claims (born in India and born on 7th November 1888) can be inferred from the context.
  • Faithfulness score = 2/2 = 1.0

Low faithfulness answer: Raman was born in India on 10th November 1888.

    • Only the claim “born in India” is supported by the context.
    • Faithfulness score = 1/2 = 0.5

2. Answer Relevance:

The Answer Relevance metric assesses how closely a generated answer aligns with the original prompt. Higher scores indicate better relevance, while lower scores suggest incompleteness or redundancy.

Calculation

To compute Answer Relevance, the following steps are involved:

  1. Generate Artificial Questions: Create multiple questions based on the generated answer. The default number is 3.
  2. Embed Questions: Convert the original question and the generated questions into numerical representations (embeddings).
  3. Calculate Cosine Similarity: Determine the cosine similarity between the embedding of the original question and each generated question embedding.
  4. Compute Mean Cosine Similarity: Calculate the average cosine similarity of all generated questions to the original question. This value is the Answer Relevance score.

Formula:

answer_relevance = (1/N) * Σ(cos (Egi, Eo))

Where:

  • N is the number of generated questions (default: 3)
  • Egi is the embedding of the i-th generated question
  • Eo is the embedding of the original question

 

Note: While the cosine similarity ranges from -1 to 1, in practice, the Answer Relevance score typically falls between 0 and 1.

Interpretation
  • Higher scores indicate a strong alignment between the generated answer and the original question.
  • Lower scores suggest the answer might be incomplete, irrelevant, or redundant.

By evaluating Answer Relevance, we can assess the quality and appropriateness of the generated response.

3. Context Precision

Context Precision measures the accuracy of ranking relevant information within a set of contexts. It evaluates how effectively the most pertinent information is placed at the top of the ranked list.

Calculation

The Context Precision metric is calculated as follows:

Context Precision@K = Σ(Precision@k * vk) / Total number of relevant items in the top K results

Where:

  • K is the total number of chunks in the contexts.
  • Precision@k is the proportion of relevant items among the top k ranked items.
  • vk is a binary indicator (0 or 1) denoting whether the item at rank k is relevant.

Precision@k is calculated as:

Precision@k = true positives@k / (true positives@k + false positives@k)

Interpretation
  • Higher scores indicate better context precision, meaning relevant information is consistently ranked higher.
  • Lower scores suggest that relevant information is scattered or ranked lower than less relevant content.

 

Example [1],2

Question: Where is India and what is its capital?

Ground Truth: India is in South Asia and its capital is New Delhi.

High Context Precision:

  • Both relevant pieces of information (“India is in South Asia” and “its capital is Paris”) are present in the first context.

Low Context Precision:

  • One relevant piece of information (“India is in South Asia”) is in the second context, while the other (“its capital is New Delhi”) is in the first.

By prioritizing relevant information at the top of the ranked contexts, Context Precision helps improve the overall performance of systems that rely on context for information retrieval or generation.

4. Context Recall

Context Recall measures the extent to which information from the retrieved context aligns with the ground truth answer. A higher score indicates better alignment.

Calculation

To calculate context recall:

  • Identify claims: Extract claims from the ground truth answer.
  • Check attribution: Determine if each claim can be supported by the retrieved context.
  • Calculate recall: Use the following formula:

 

context recall = |GT claims attributed to context| / |Total number of claims in GT|

Interpretation
  • A score closer to 1 indicates strong alignment between the retrieved context and the ground truth answer.
  • A lower score suggests missing information in the retrieved context.

 

Example [1,2]

Question: Where is India and what is its capital?

Ground Truth: India is in South Asia and its capital is New Delhi.

  • High context recall: The retrieved context mentions both “India is in South Asia” and “New Delhi, its capital”.
  • Low context recall: The retrieved context only mentions “India is in South Asia” but not its capital.

By evaluating context recall, we can assess the quality and comprehensiveness of the retrieved context in relation to the desired information.

5. Context Entities Recall

Context Entities Recall measures how effectively a retrieved context covers the entities present in the ground truth. It’s particularly useful in fact-based domains like tourism or historical questions answering where entities are crucial.

Calculation

The formula for context entities recall is:

context entity recall = |CE ∩ GE| / |GE|

Where:

  • CE is the set of entities present in the retrieved context.
  • GE is the set of entities present in the ground truth.

Essentially, it calculates the ratio of entities found in both the context and the ground truth to the total number of entities in the ground truth.

Interpretation
  • A higher score indicates better entity coverage in the retrieved context.
  • A lower score suggests that the context is missing important entities from the ground truth.

 

Example [1,2]

Ground Truth: The Qutub Minar is a red sandstone and marble minaret located in Delhi, India. It was commissioned by Qutb-ud-din Aibak in 1192 to celebrate his victory over the last Hindu kingdom of Delhi.  

Entities in Ground Truth (GE): Qutub Minar, red sandstone, marble, Delhi, Qutb-ud-din Aibak

High Entity Recall Context: The Qutub Minar is a remarkable architectural structure in Delhi, India, built by Qutb-ud-din Aibak in 1192. This towering minaret is made of red sandstone and marble, showcasing intricate carvings and inscriptions from the Islamic era.

Low Entity Recall Context: The Qutub Minar is a famous historical monument in India. It stands tall as a UNESCO World Heritage Site and is visited by numerous tourists each year for its stunning architecture and historical significance.

In the high entity recall context, most entities from the ground truth are included, while in the low entity recall context, key entities like red sandstone, marble, and Qutb-ud-din Aibak are missing.

By evaluating context entities recall, you can assess how well the retrieved context aligns with the entity-based information in the ground truth.

6. Answer Semantic Similarity

Answer Semantic Similarity evaluates how closely a generated answer matches the ground truth in terms of meaning. This metric goes beyond simple lexical overlap to capture the underlying semantic relationship between the two texts.

Calculation

Typically, a cross-encoder model is used to compute the semantic similarity score. This model takes the ground truth and the generated answer as input and produces a similarity score between 0 and 1. A higher score indicates greater semantic similarity.

Interpretation
  • Higher scores indicate that the generated answer conveys a similar meaning to the ground truth.
  • Lower scores suggest that the generated answer is semantically different from the ground truth.

 

Example [1,2]

Ground Truth: C.V. Raman’s discovery of the Raman effect revolutionized our understanding of light scattering.

  • High similarity answer: Raman’s groundbreaking discovery of the Raman effect transformed our comprehension of light scattering
  • Low similarity answer: Jagadish Chandra Bose’s work on radio waves significantly advanced early wireless communication research.

By measuring answer semantic similarity, we can assess the quality of generated answers in a more nuanced way than traditional metrics like exact match or F1-score.

7. Answer Correctness

Answer Correctness is a metric that assesses the accuracy of a generated answer compared to the ground truth. It combines both semantic and factual similarity for a comprehensive evaluation.

Key Components
  • Semantic Similarity: Measures how closely the meaning of the generated answer aligns with the ground truth.
  • Factual Similarity: Evaluates the accuracy of the factual information presented in the answer.
 
Calculation
  • Calculate Semantic Similarity: Use a cross-encoder model or other techniques to determine the semantic overlap between the answer and ground truth.
  • Calculate Factual Similarity: Employ fact-checking or knowledge base comparison to assess the accuracy of the factual claims.
  • Combine Scores: Assign weights to semantic and factual similarity based on the specific use case. Combine the weighted scores to obtain the final answer correctness score.
  • Apply Threshold (Optional): If desired, round the final score to a binary value (0 or 1) using a predefined threshold.

 

Example [1,2]

Ground Truth: Ignitarium was established in 2012 in Bangalore.

  • High answer correctness: In 2012, Ignitarium was established in Bangalore. (Both semantic and factual similarity are high)
  • Low answer correctness: Ignitarium was established in Kochi in 2012. (Semantic similarity might be reasonable, but factual similarity is low)

 

Additional Considerations
  • Complex Answers: For answers with multiple components, consider breaking them down into smaller units for evaluation.
  • Domain-Specific Knowledge: Incorporate domain-specific knowledge bases or ontologies to enhance factual accuracy assessment.
  • Human Evaluation: Human judgment can be valuable for complex or ambiguous cases.

By combining semantic and factual similarity, answer correctness provides a more robust evaluation of generated text compared to traditional metrics like exact match or F1-score.

8. Aspect Critique

Aspect Critique is a binary classification method used to evaluate text submissions based on predefined aspects or user-defined criteria.

Key Features
  • Predefined Aspects: Offers a set of standard aspects like harmfulness, correctness, coherence, conciseness, etc.
  • Custom Aspects: Allows users to define specific criteria tailored to their needs.
  • Binary Output: Provides a simple yes/no answer for each aspect.
  • Strictness Parameter: Controls the sensitivity of the evaluation.
 
How it Works
  • Define Aspects: Select from predefined aspects or create custom ones.
  • Evaluate Submission: Analyze the text against each defined aspect.
  • Assign Binary Score: Determine if the submission aligns with the aspect (1) or not (0).

 

Example

Predefined Aspects: harmfulness, correctness

Submission: “The sky is blue, and the grass is green.”

  • Harmfulness: 0 (not harmful)
  • Correctness: 1 (correct)
 
Strictness Parameter

The strictness parameter influences the model’s decision-making. A higher strictness value makes the model more conservative in assigning positive scores.

Applications

Aspect Critique can be used for:

  • Content moderation: Identifying harmful or inappropriate content.
  • Quality assurance: Evaluating the correctness and coherence of text.
  • Text summarization: Assessing the conciseness of summaries.
  • Custom evaluation: Creating specific criteria for different use cases.

By providing a clear and binary evaluation, Aspect Critique offers a straightforward way to assess text submissions based on predefined or custom criteria.

Conclusion

In conclusion, the RAGAS framework provides a valuable tool for evaluating Retrieval Augmented Generation (RAG) pipelines. Unlike traditional metrics that focus primarily on quantitative aspects like n-gram overlap and prediction accuracy, RAGAS offers a more comprehensive and nuanced assessment. It addresses various dimensions of performance, which may include relevance, accuracy, and other qualitative aspects, depending on the specific implementation. This broader approach helps capture the full range of a model’s capabilities and ensures that it not only generates correct information but also delivers it in a coherent, contextually appropriate, and user-friendly manner. By using RAGAS, developers and researchers can gain deeper insights into their models’ strengths and weaknesses, leading to better optimization and more effective real-world applications.

References

Scroll to Top

Human Pose Detection & Classification

Some Buildings in a city

Features:

  • Suitable for real time detection on edge devices
  • Detects human pose / key points and recognizes movement / behavior
  • Light weight deep learning models with good accuracy and performance

Target Markets:

  • Patient Monitoring in Hospitals
  • Surveillance
  • Sports/Exercise Pose Estimation
  • Retail Analytics

OCR / Pattern Recognition

Some Buildings in a city

Use cases :

  • Analog dial reading
  • Digital meter reading
  • Label recognition
  • Document OCR

Highlights :

  • Configurable for text or pattern recognition
  • Simultaneous Analog and Digital Dial reading
  • Lightweight implementation

Behavior Monitoring

Some Buildings in a city

Use cases :

  • Fall Detection
  • Social Distancing

Highlights :

  • Can define region of interest to monitor
  • Multi-subject monitoring
  • Multi-camera monitoring
  • Alarm triggers

Attire & PPE Detection

Some Buildings in a city

Use cases :

  • PPE Checks
  • Disallowed attire checks

Use cases :

  • Non-intrusive adherence checks
  • Customizable attire checks
  • Post-deployment trainable

 

Request for Video





    Real Time Color Detection​

    Use cases :

    • Machine vision applications such as color sorter or food defect detection

    Highlights :

    • Color detection algorithm with real time performance
    • Detects as close to human vison as possible including color shade discrimination
    • GPGPU based algorithm on NVIDIA CUDA and Snapdragon Adreno GPU
    • Extremely low latency (a few 10s of milliseconds) for detection
    • Portable onto different hardware platforms

    Missing Artifact Detection

    Use cases :

    • Detection of missing components during various stages of manufacturing of industrial parts
    • Examples include : missing nuts and bolts, missing ridges, missing grooves on plastic and metal blocks

    Highlights :

    • Custom neural network and algorithms to achieve high accuracy and inference speed
    • Single-pass detection of many categories of missing artifacts
    • In-field trainable neural networks with dynamic addition of new artifact categories
    • Implementation using low cost cameras and not expensive machine-vision cameras
    • Learning via the use of minimal training sets
    • Options to implement the neural network on GPU or CPU based systems

    Real Time Manufacturing Line Inspection

    Use cases :

    • Detection of defects on the surface of manufactured goods (metal, plastic, glass, food, etc.)
    • Can be integrated into the overall automated QA infrastructure on an assembly line.

    Highlights :

    • Custom neural network and algorithms to achieve high accuracy and inference speed
    • Use of consumer or industrial grade cameras
    • Requires only a few hundred images during the training phase
    • Supports incremental training of the neural network with data augmentation
    • Allows implementation on low cost GPU or CPU based platforms

    Ground Based Infrastructure analytics

    Some Buildings in a city

    Use cases :

    • Rail tracks (public transport, mining, etc.)
    • Highways
    • Tunnels

    Highlights :

    • Analysis of video and images from 2D & 3D RGB camera sensors
    • Multi sensor support (X-ray, thermal, radar, etc.)
    • Detection of anomalies in peripheral areas of core infrastructure (Ex: vegetation or stones near rail tracks)

    Aerial Analytics

    Use cases :

    • Rail track defect detection
    • Tower defect detection: Structural analysis of Power
      transmission towers
    • infrastructure mapping

    Highlights :

    • Defect detection from a distance
    • Non-intrusive
    • Automatic video capture with perfectly centered ROI
    • No manual intervention is required by a pilot for
      camera positioning

    SANJAY JAYAKUMAR

    Co-founder & CEO

     

    Founder and Managing director of Ignitarium, Sanjay has been responsible for defining Ignitarium’s core values, which encompass the organisation’s approach towards clients, partners, and all internal stakeholders, and in establishing an innovation and value-driven organisational culture.

     

    Prior to founding Ignitarium in 2012, Sanjay spent the initial 22 years of his career with the VLSI and Systems Business unit at Wipro Technologies. In his formative years, Sanjay worked in diverse engineering roles in Electronic hardware design, ASIC design, and custom library development. Sanjay later handled a flagship – multi-million dollar, 600-engineer strong – Semiconductor & Embedded account owning complete Delivery and Business responsibility.

     

    Sanjay graduated in Electronics and Communication Engineering from College of Engineering, Trivandrum, and has a Postgraduate degree in Microelectronics from BITS Pilani.

     

    Request Free Demo




      RAMESH EMANI Board Member

      RAMESH EMANI

      Board Member

      Ramesh was the Founder and CEO of Insta Health Solutions, a software products company focused on providing complete hospital and clinic management solutions for hospitals and clinics in India, the Middle East, Southeast Asia, and Africa. He raised Series A funds from Inventus Capital and then subsequently sold the company to Practo Technologies, India. Post-sale, he held the role of SVP and Head of the Insta BU for 4 years. He has now retired from full-time employment and is working as a consultant and board member.

       

      Prior to Insta, Ramesh had a 25-year-long career at Wipro Technologies where he was the President of the $1B Telecom and Product Engineering Solutions business heading a team of 19,000 people with a truly global operations footprint. Among his other key roles at Wipro, he was a member of Wipro's Corporate Executive Council and was Chief Technology Officer.

       

      Ramesh is also an Independent Board Member of eMIDs Technologies, a $100M IT services company focused on the healthcare vertical with market presence in the US and India.

       

      Ramesh holds an M-Tech in Computer Science from IIT-Kanpur.

      ​Manoj Thandassery

      VP – Sales & Business Development

      Manoj Thandassery is responsible for the India business at Ignitarium. He has over 20 years of leadership and business experience in various industries including the IT and Product Engineering industry. He has held various responsibilities including Geo head at Sasken China, Portfolio head at Wipro USA, and India & APAC Director of Sales at Emeritus. He has led large multi-country teams of up to 350 employees. Manoj was also an entrepreneur and has successfully launched and scaled, via multiple VC-led investment rounds, an Edtech business in the K12 space that was subsequently sold to a global Edtech giant.
      An XLRI alumnus, Manoj divides his time between Pune and Bangalore.

       

      MALAVIKA GARIMELLA​

      General Manager - Marketing

      A professional with a 14-year track record in technology marketing, Malavika heads marketing in Ignitarium. Responsible for all branding, positioning and promotional initiatives in the company, she has collaborated with technical and business teams to further strengthen Ignitarium's positioning as a key E R&D services player in the ecosystem.

      Prior to Ignitarium, Malavika has worked in with multiple global tech startups and IT consulting companies as a marketing consultant. Earlier, she headed marketing for the Semiconductor & Systems BU at Wipro Technologies and worked at IBM in their application software division.

      Malavika completed her MBA in Marketing from SCMHRD, Pune, and holds a B.E. degree in Telecommunications from RVCE, Bengaluru.

       

      PRADEEP KUMAR LAKSHMANAN

      VP - Operations

      Pradeep comes with an overall experience of 26 years across IT services and Academia. In his previous role at Virtusa, he played the role of Delivery Leader for the Middle East geography. He has handled complex delivery projects including the transition of large engagements, account management, and setting up new delivery centers.

      Pradeep graduated in Industrial Engineering and Management, went on to secure an MBA from CUSAT, and cleared UGN Net in Management. He also had teaching stints at his alma mater, CUSAT, and other management institutes like DCSMAT. A certified P3O (Portfolio, Program & Project Management) from the Office of Government Commerce, UK, Pradeep has been recognized for key contributions in the Management domain, at his previous organizations, Wipro & Virtusa.

      In his role as the Head of Operations at Ignitarium, Pradeep leads and manages operational functions such as Resource Management, Procurement, Facilities, IT Infrastructure, and Program Management office.

       

      SONA MATHEW Director – Human Resources

      SONA MATHEW

      AVP – Human Resources

      Sona heads Human Resource functions - Employee Engagement, HR Operations and Learning & Development – at Ignitarium. Her expertise include deep and broad experience in strategic people initiatives, performance management, talent transformation, talent acquisition, people engagement & compliance in the Information Technology & Services industry.

       

      Prior to Ignitarium, Sona has had held diverse HR responsibilities at Litmus7, Cognizant and Wipro.

       

      Sona graduated in Commerce from St. Xaviers College and did her MBA in HR from PSG College of Technology.

       

      ASHWIN RAMACHANDRAN

      Vice President - Sales

      As VP of Sales, Ashwin is responsible for Ignitarium’s go-to-market strategy, business, client relationships, and customer success in the Americas. He brings in over a couple of decades of experience, mainly in the product engineering space with customers from a wide spectrum of industries, especially in the Hi-Tech/semiconductor and telecom verticals.

       

      Ashwin has worked with the likes of Wipro, GlobalLogic, and Mastek, wherein unconventional and creative business models were used to bring in non-linear revenue. He has strategically diversified, de-risked, and grown his portfolios during his sales career.

       

      Ashwin strongly believes in the customer-first approach and works to add value and enhance the experiences of our customers.

       

      AZIF SALY Director – Sales

      AZIF SALY

      Vice President – Sales & Business Development

      Azif is responsible for go-to-market strategy, business development and sales at Ignitarium. Azif has over 14 years of cross-functional experience in the semiconductor product & service spaces and has held senior positions in global client management, strategic account management and business development. An IIM-K alumnus, he has been associated with Wipro, Nokia and Sankalp in the past.

       

      Azif handled key accounts and sales process initiatives at Sankalp Semiconductors. Azif has pursued entrepreneurial interests in the past and was associated with multiple start-ups in various executive roles. His start-up was successful in raising seed funds from Nokia, India. During his tenure at Nokia, he played a key role in driving product evangelism and customer success functions for the multimedia division.

       

      At Wipro, he was involved in customer engagement with global customers in APAC and US.

       

      RAJU KUNNATH Vice President – Enterprise & Mobility

      RAJU KUNNATH

      Distinguished Engineer – Digital

      At Ignitarium, Raju's charter is to architect world class Digital solutions at the confluence of Edge, Cloud and Analytics. Raju has over 25 years of experience in the field of Telecom, Mobility and Cloud. Prior to Ignitarium, he worked at Nokia India Pvt. Ltd. and Sasken Communication Technologies in various leadership positions and was responsible for the delivery of various developer platforms and products.

       

      Raju graduated in Electronics Engineering from Model Engineering College, Cochin and has an Executive Post Graduate Program (EPGP) in Strategy and Finance from IIM Kozhikode.

       

      PRADEEP SUKUMARAN Vice President – Business Strategy & Marketing

      PRADEEP SUKUMARAN

      Vice President - Software Engineering

      Pradeep heads the Software Engineering division, with a charter to build and grow a world-beating delivery team. He is responsible for all the software functions, which includes embedded & automotive software, multimedia, and AI & Digital services

      At Ignitarium, he was previously part of the sales and marketing team with a special focus on generating a sales pipeline for Vision Intelligence products and services, working with worldwide field sales & partner ecosystems in the U.S  Europe, and APAC.

      Prior to joining Ignitarium in 2017, Pradeep was Senior Solutions Architect at Open-Silicon, an ASIC design house. At Open-Silicon, where he spent a good five years, Pradeep was responsible for Front-end, FPGA, and embedded SW business development, marketing & technical sales and also drove the IoT R&D roadmap. Pradeep started his professional career in 2000 at Sasken, where he worked for 11 years, primarily as an embedded multimedia expert, and then went on to lead the Multimedia software IP team.

      Pradeep is a graduate in Electronics & Communication from RVCE, Bangalore.

       

      SUJEET SREENIVASAN Vice President – Embedded

      SUJEET SREENIVASAN

      Vice President – Automotive Technology

       

      Sujeet is responsible for driving innovation in Automotive software, identifying Automotive technology trends and advancements, evaluating their potential impact, and development of solutions to meet the needs of our Automotive customers.

      At Ignitarium, he was previously responsible for the growth and P&L of the Embedded Business unit focusing on Multimedia, Automotive, and Platform software.

      Prior to joining Ignitarium in 2016, Sujeet has had a career spanning more than 16 years at Wipro. During this stint, he has played diverse roles from Solution Architect to Presales Lead covering various domains. His technical expertise lies in the areas of Telecom, Embedded Systems, Wireless, Networking, SoC modeling, and Automotive. He has been honored as a Distinguished Member of the Technical Staff at Wipro and has multiple patents granted in the areas of Networking and IoT Security.

      Sujeet holds a degree in Computer Science from Government Engineering College, Thrissur.

       

      RAJIN RAVIMONY Distinguished Engineer

      RAJIN RAVIMONY

      Distinguished Engineer

       

      At Ignitarium, Rajin plays the role of Distinguished Engineer for complex SoCs and systems. He's an expert in ARM-based designs having architected more than a dozen SoCs and played hands-on design roles in several tens more. His core areas of specialization include security and functional safety architecture (IEC61508 and ISO26262) of automotive systems, RTL implementation of math intensive signal processing blocks as well as design of video processing and related multimedia blocks.

       

      Prior to Ignitarium, Rajin worked at Wipro Technologies for 14 years where he held roles of architect and consultant for several VLSI designs in the automotive and consumer domains.

       

      Rajin holds an MS in Micro-electronics from BITS Pilani.

       

      SIBY ABRAHAM Executive Vice President, Strategy

      SIBY ABRAHAM

      Executive Vice President, Strategy

       

      As EVP, of Strategy at Ignitarium, Siby anchors multiple functions spanning investor community relations, business growth, technology initiatives as well and operational excellence.

       

      Siby has over 31 years of experience in the semiconductor industry. In his last role at Wipro Technologies, he headed the Semiconductor Industry Practice Group where he was responsible for business growth and engineering delivery for all of Wipro’s semiconductor customers. Prior to that, he held a vast array of crucial roles at Wipro including Chief Technologist & Vice President, CTO Office, Global Delivery Head for Product Engineering Services, Business Head of Semiconductor & Consumer Electronics, and Head of Unified Competency Framework. He was instrumental in growing Wipro’s semiconductor business to over $100 million within 5 years and turning around its Consumer Electronics business in less than 2 years. In addition, he was the Engineering Manager for Enthink Inc., a semiconductor IP-focused subsidiary of Wipro. Prior to that, Siby was the Technical Lead for several of the most prestigious system engineering projects executed by Wipro R&D.

       

      Siby has held a host of deeply impactful positions, which included representing Wipro in various World Economic Forum working groups on Industrial IOT and as a member of IEEE’s IOT Steering Committee.

       

      He completed his MTech. in Electrical Engineering (Information and Control) from IIT, Kanpur and his BTech. from NIT, Calicut

       

      SUDIP NANDY

      Board Member

       

      An accomplished leader with over 40 years of experience, Sudip has helped build and grow companies in India, the US and the UK.

      He has held the post of Independent Director and Board Member for several organizations like Redington Limited, Excelra, Artison Agrotech, GeBBS Healthcare Solutions, Liquid Hub Inc. and ResultsCX.

      Most recently, Sudip was a Senior Advisor at ChrysCapital, a private equity firm where he has also been the Managing Director and Operating Partner for IT for the past 5 years. During his tenure, he has been Executive Chairman of California-headquartered Infogain Corporation and the non-Exec Chair on the board of a pioneering electric-2-wheeler company Ampere Vehicles, which is now a brand of Greaves Cotton Ltd.

      Earlier on in his career, Sudip has been the CEO and then Chairman India for Aricent. Prior to that, he had spent 25+ years in Wipro where he has been the Head of US business, Engineering R&D Services, and later the Head of EU Operations.

      Sudip is an active investor in several interesting startups in India and overseas, which mostly use technology for the social good, encompassing hyperlocal, healthcare, rural development, farmer support and e2W ecosystem. He also spends time as a coach and mentor for several CEOs in this role.

       

      SUJEETH JOSEPH Chief Product Officer

      SUJEETH JOSEPH

      Chief Technology Officer

       

      As CTO, Sujeeth is responsible for defining the technology roadmap, driving IP & solution development, and transitioning these technology components into practically deployable product engineering use cases.

       

      With a career spanning over 30+ years, Sujeeth Joseph is a semiconductor industry veteran in the SoC, System and Product architecture space. At SanDisk India, he was Director of Architecture for the USD $2B Removable Products Group. Simultaneously, he also headed the SanDisk India Patenting function, the Retail Competitive Analysis Group and drove academic research programs with premier Indian academic Institutes. Prior to SanDisk, he was Chief Architect of the Semiconductor & Systems BU (SnS) of Wipro Technologies. Over a 19-year career at Wipro, he has played hands-on and leadership roles across all phases of the ASIC and System design flow.

       

      He graduated in Electronics Engineering from Bombay University in 1991.

       

      SUJITH MATHEW IYPE Co-founder & CTO

      SUJITH MATHEW IYPE

      Co-founder & COO

       

      As Ignitarium's Co-founder and COO, Sujith is responsible for driving the operational efficiency and streamlining process across the organization. He is also responsible for the growth and P&L of the Semiconductor Business Unit.

       

      Apart from establishing a compelling story in VLSI, Sujith was responsible for Ignitarium's foray into nascent technology areas like AI, ML, Computer Vision, and IoT, nurturing them in our R&D Lab - "The Crucible".

       

      Prior to founding Ignitarium, Sujith played the role of a VLSI architect at Wipro Technologies for 13 years. In true hands-on mode, he has built ASICs and FPGAs for the Multimedia, Telecommunication, and Healthcare domains and has provided technical leadership for many flagship projects executed by Wipro.

       

      Sujith graduated from NIT - Calicut in the year 2000 in Electronics and Communications Engineering and thereafter he has successfully completed a one-year executive program in Business Management from IIM Calcutta.

       

      RAMESH SHANMUGHAM Co-founder & COO

      RAMESH SHANMUGHAM

      Co-founder & CRO

      As Co-founder and Chief Revenue Officer of Ignitarium, Ramesh has been responsible for global business and marketing as well as building trusted customer relationships upholding the company's core values.

      Ramesh has over 25 years of experience in the Semiconductor Industry covering all aspects of IC design. Prior to Ignitarium, Ramesh was a key member of the senior management team of the semiconductor division at Wipro Technologies. Ramesh has played key roles in Semiconductor Delivery and Pre-sales at a global level.

      Ramesh graduated in Electronics Engineering from Model Engineering College, Cochin, and has a Postgraduate degree in Microelectronics from BITS Pilani.