Photonic Design Automation Market Size and Forecasts, Global and Regional Share, Trends, and Growth Opportunity Analysis Report Coverage: By Component, Deployment, Organization Size, and Application

List of Tables

The Photonic design automation market size was valued at US$ 1.39 billion in 2022 and is expected to reach US$ 3.90 billion by 2030; it is estimated to record a CAGR of 13.8% from 2022 to 2030.

The integration of photonics into electronic design automation (EDA) tools is a significant trend in the photonic design automation market. Established EDA vendors recognize the potential of the emerging photonic design automation market and incorporate photonics-specific features and capabilities into their existing tools. This integration enables designers to seamlessly incorporate photonics components into their designs, streamlining the design process and optimizing the performance and functionality of photonic devices. By integrating photonics into EDA tools, designers can leverage familiar design environments and workflows, reducing the learning curve associated with specialized photonic design tools. The integration of photonics into EDA tools also facilitates the convergence of electronics and photonics, enabling the development of integrated electronic-photonic circuits. This convergence is crucial for the advancement of technologies such as silicon photonics, where the sharing of tools, processes, and simulation models between photonics and IC design accelerates the development of photonic design automation market. Overall, the integration of photonics into EDA tools reflects the industry's recognition of the growing importance of photonics and the need for efficient design processes and optimization techniques in the photonic field. It enables designers to harness the potential of photonics and seamlessly incorporate it into their electronic designs.

Advancements in compact modeling and simulation tools are expected to have a significant impact on the photonic design automation market. These tools play a crucial role in the convergence of electronics and photonics, enabling faster and more efficient design processes. Compact modeling refers to the development of simplified mathematical models that precisely denote the behavior of complex photonic devices. These models allow designers to simulate and analyze the performance of photonic components without the need for expensive and time-consuming device-level simulations. By incorporating compact modeling into design automation tools, designers can streamline the design process and optimize the performance of integrated electronic-photonic circuits. These tools facilitate the transition from electronic-photonic co-design to the development of fully integrated circuits, enabling designers to achieve high performance and efficiency. Such advantages enable higher applications and promote photonic design automation market growth.

The integration of compact modeling and simulation tools into the photonic design automation workflow enables designers to explore different design options, evaluate the impact of various parameters, and make informed decisions. This leads to faster design iterations, reduced time-to-market, and improved overall design quality. The importance of compact modeling and simulation tools offered by photonic design automation market players is recognized by both industry and academia. Established electronic design automation vendors are incorporating photonics-specific features and capabilities into their existing tools, allowing designers to integrate photonics components into their designs seamlessly.

The solution segment of the photonic design automation market encompasses a variety of software and tools that facilitate the design, simulation, and verification of photonic integrated circuits (PICs) and other photonic devices. These solutions are purpose-built to address the distinctive challenges and needs of the photonics industry. Photonic design automation (PDA) tools are instrumental in expediting the development and enhancement of photonic devices by equipping designers with advanced capabilities for simulation, modeling, and analysis. These tools enable designers to effectively create and validate intricate photonic circuits, optimize performance, and ensure efficient production processes. Software tools that enable designers to create and lay out photonic circuits have components such as waveguides, modulators, detectors, and filters. These tools often provide a user-friendly interface and advanced design capabilities to streamline the design process. The photonic design automation market growth is driven by the growing demand for photonic devices in various applications, including telecommunications, data centers, healthcare, sensing, and imaging. As the photonics industry continues to evolve and expand, the need for efficient and reliable design tools becomes increasingly important.

The academic research segment of the photonic design automation market refers to the involvement of universities, research institutions, and academic professionals in conducting research and development activities related to photonic design and associated services. This segment plays a crucial role in advancing the field of photonics and driving innovation in design methodologies, algorithms, and tools. Academic institutions and research organizations actively engage in research and development activities to explore new concepts, algorithms, and techniques. They thus avail the different solutions offered by photonic design automation market players. They focus on developing innovative solutions to address the challenges and limitations in the design of photonic components, systems, and integrated circuits, by utilizing such solutions. This research contributes to the advancement of the field and provides valuable insights for industry practitioners. Academic researchers often collaborate with industry experts, other academic institutions, and research consortia to share knowledge, exchange ideas, and collaborate on joint research projects. These collaborations foster interdisciplinary approaches and enable the integration of diverse perspectives in photonic design automation. The academic research segment plays a vital role in facilitating collaboration and knowledge sharing within the photonics industry. For instance, the University of Texas Design Automation Laboratory (UTDA) focuses on the R&D of design automation algorithms, methodologies, and tools for optics/photonics, electronics, and emerging technologies in the photonic design automation market.

Industrial research and manufacturing companies develop and utilize design automation tools specifically tailored for the photonics industry. These tools enable designers to automate various stages of the design process, such as layout generation, simulation, verification, and optimization. By leveraging these tools, companies can accelerate the design cycle, improve design quality, and reduce time-to-market for photonic products. The industrial research and manufacturing segment focuses on optimizing the manufacturing processes for photonic devices. This includes developing advanced fabrication techniques, process control methodologies, and yield enhancement strategies. By improving manufacturing efficiency and yield rates, companies can achieve cost-effective production of high-quality photonic components and systems. Photonic design automation market players often collaborate with photonic manufacturers to enhance and promote their products. For instance, in March 2022, Cadence Design Systems collaborated with GlobalFoundries for accelerating silicon photonics IC development for hyperscale computing, 5G communications, and aerospace systems among others. Such collaborations greatly enhance the awareness regarding such products, and also promote photonic design automation market growth.

The global photonic design automation market is segmented based on component, deployment, organization size, and application. Based on component, the photonic design automation market is divided into solutions and services. In terms of deployment, the photonic design automation market is bifurcated into on-premise and cloud. By organization size, the photonic design automation market is bifurcated into SMEs and large enterprises. Based on application, the photonic design automation market is divided into academic research and industrial research & manufacturing. By geography, the photonic design automation market is segmented into North America, Europe, Asia Pacific (APAC), and Rest of the World (RoW). AIM Photonics Inc, Ansys Inc, Cadence Design Systems Inc, LioniX International BV, Luceda Photonics, Optiwave Systems Inc, Siemens AG, Synopsys Inc, SystemLab Inc, and VPlphotonics GmbH are among the prominent photonic design automation market players.

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Product Code: TIPRE00033004

1. Introduction

1.1 The Insight Partners Research Report Guidance
1.2 Market Segmentation

2. Executive Summary

2.1 Key Insights
2.2 Market Attractiveness

3. Research Methodology

3.1 Coverage
3.2 Secondary Research
3.3 Primary Research

4. Photonic Design Automation Market Landscape

4.1 Overview
4.2 PEST Analysis
4.3 Ecosystem Analysis
- 4.3.1 List of Vendors in the Value Chain:

5. Photonic Design Automation Market - Key Market Dynamics

5.1 Photonic Design Automation Market - Key Market Dynamics
5.2 Market Drivers
- 5.2.1 Growing Demand for Automation
- 5.2.2 Increasing Need for Efficiency and Accuracy
5.3 Market Restraints
- 5.3.1 Lack of Awareness Regarding Benefits and Capabilities of Photonic Design Automation
5.4 Market Opportunities
- 5.4.1 Advancements in Photonic Devices
- 5.4.2 Emphasis on High Performance and Environmentally Sustainable Solutions
5.5 Future Trends
- 5.5.1 Integration of Photonics in Electronic Design Automation (EDA) Tools
- 5.5.2 Advancements in Compact Modelling and Simulation Tools
5.6 Impact of Drivers and Restraints:

6. Photonic Design Automation Market - Global Market Analysis

6.1 Photonic Design Automation Market Revenue (US$ Million), 2022 - 2030
6.2 Photonic Design Automation Market Forecast and Analysis

7. Photonic Design Automation Market Analysis - Component

7.1 Solution
- 7.1.1 Overview
- 7.1.2 Solution Market, Revenue and Forecast to 2030 (US$ Million)
7.2 Service
- 7.2.1 Overview
- 7.2.2 Service Market, Revenue and Forecast to 2030 (US$ Million)

8. Photonic Design Automation Market Analysis - Deployment

8.1 On-Premise
- 8.1.1 Overview
- 8.1.2 On-Premise Market, Revenue and Forecast to 2030 (US$ Million)
8.2 Cloud
- 8.2.1 Overview
- 8.2.2 Cloud Market, Revenue and Forecast to 2030 (US$ Million)

9. Photonic Design Automation Market Analysis - Organization Size

9.1 SMEs
- 9.1.1 Overview
- 9.1.2 SMEs Market, Revenue and Forecast to 2030 (US$ Million)
9.2 Large Enterprises
- 9.2.1 Overview
- 9.2.2 Large Enterprises Market, Revenue and Forecast to 2030 (US$ Million)

10. Photonic Design Automation Market Analysis - Application

10.1 Academic Research
- 10.1.1 Overview
- 10.1.2 Academic Research Market, Revenue and Forecast to 2030 (US$ Million)
10.2 Industrial Research & Manufacturing
- 10.2.1 Overview
- 10.2.2 Industrial Research & Manufacturing Market, Revenue and Forecast to 2030 (US$ Million)

11. Photonic Design Automation Market - Geographical Analysis

11.1 Overview
11.2 North America
- 11.2.1 North America Photonic Design Automation Market Overview
- 11.2.2 North America Photonic Design Automation Market Revenue and Forecasts to 2030 (US$ Mn)
- 11.2.3 North America Photonic Design Automation Market Breakdown by Component
  - 11.2.3.1 North America Photonic Design Automation Market Revenue and Forecasts and Analysis - By Component
- 11.2.4 North America Photonic Design Automation Market Breakdown by Deployment
  - 11.2.4.1 North America Photonic Design Automation Market Revenue and Forecasts and Analysis - By Deployment
- 11.2.5 North America Photonic Design Automation Market Breakdown by Organization Size
  - 11.2.5.1 North America Photonic Design Automation Market Revenue and Forecasts and Analysis - By Organization Size
- 11.2.6 North America Photonic Design Automation Market Breakdown by Application
  - 11.2.6.1 North America Photonic Design Automation Market Revenue and Forecasts and Analysis - By Application
- 11.2.7 North America Photonic Design Automation Market Revenue and Forecasts and Analysis - By Country
  - 11.2.7.1 North America Photonic Design Automation Market Revenue and Forecasts and Analysis - By Country
  - 11.2.7.2 US Photonic Design Automation Market Revenue and Forecasts to 2030 (US$ Mn)
    - 11.2.7.2.1 US Photonic Design Automation Market Breakdown, by Component
    - 11.2.7.2.2 US Photonic Design Automation Market Breakdown, by Deployment
    - 11.2.7.2.3 US Photonic Design Automation Market Breakdown, by Organization Size
    - 11.2.7.2.4 US Photonic Design Automation Market Breakdown, by Application
  - 11.2.7.3 Canada Photonic Design Automation Market Revenue and Forecasts to 2030 (US$ Mn)
    - 11.2.7.3.1 Canada Photonic Design Automation Market Breakdown, by Component
    - 11.2.7.3.2 Canada Photonic Design Automation Market Breakdown, by Deployment
    - 11.2.7.3.3 Canada Photonic Design Automation Market Breakdown, by Organization Size
    - 11.2.7.3.4 Canada Photonic Design Automation Market Breakdown, by Application
11.3 Europe
- 11.3.1 Europe Photonic Design Automation Market Overview
- 11.3.2 Europe Photonic Design Automation Market Revenue and Forecasts to 2030 (US$ Mn)
- 11.3.3 Europe Photonic Design Automation Market Breakdown by Component
  - 11.3.3.1 Europe Photonic Design Automation Market Revenue and Forecasts and Analysis - By Component
- 11.3.4 Europe Photonic Design Automation Market Breakdown by Deployment
  - 11.3.4.1 Europe Photonic Design Automation Market Revenue and Forecasts and Analysis - By Deployment
- 11.3.5 Europe Photonic Design Automation Market Breakdown by Organization Size
  - 11.3.5.1 Europe Photonic Design Automation Market Revenue and Forecasts and Analysis - By Organization Size
- 11.3.6 Europe Photonic Design Automation Market Breakdown by Application
  - 11.3.6.1 Europe Photonic Design Automation Market Revenue and Forecasts and Analysis - By Application
- 11.3.7 Europe Photonic Design Automation Market Revenue and Forecasts and Analysis - By Country
  - 11.3.7.1 Europe Photonic Design Automation Market Revenue and Forecasts and Analysis - By Country
  - 11.3.7.2 Germany Photonic Design Automation Market Revenue and Forecasts to 2030 (US$ Mn)
    - 11.3.7.2.1 Germany Photonic Design Automation Market Breakdown, by Component
    - 11.3.7.2.2 Germany Photonic Design Automation Market Breakdown, by Deployment
    - 11.3.7.2.3 Germany Photonic Design Automation Market Breakdown, by Organization Size
    - 11.3.7.2.4 Germany Photonic Design Automation Market Breakdown, by Application
  - 11.3.7.3 France Photonic Design Automation Market Revenue and Forecasts to 2030 (US$ Mn)
    - 11.3.7.3.1 France Photonic Design Automation Market Breakdown, by Component
    - 11.3.7.3.2 France Photonic Design Automation Market Breakdown, by Deployment
    - 11.3.7.3.3 France Photonic Design Automation Market Breakdown, by Organization Size
    - 11.3.7.3.4 France Photonic Design Automation Market Breakdown, by Application
  - 11.3.7.4 UK Photonic Design Automation Market Revenue and Forecasts to 2030 (US$ Mn)
    - 11.3.7.4.1 UK Photonic Design Automation Market Breakdown, by Component
    - 11.3.7.4.2 UK Photonic Design Automation Market Breakdown, by Deployment
    - 11.3.7.4.3 UK Photonic Design Automation Market Breakdown, by Organization Size
    - 11.3.7.4.4 UK Photonic Design Automation Market Breakdown, by Application
  - 11.3.7.5 Russia Photonic Design Automation Market Revenue and Forecasts to 2030 (US$ Mn)
    - 11.3.7.5.1 Russia Photonic Design Automation Market Breakdown, by Component
    - 11.3.7.5.2 Russia Photonic Design Automation Market Breakdown, by Deployment
    - 11.3.7.5.3 Russia Photonic Design Automation Market Breakdown, by Organization Size
    - 11.3.7.5.4 Russia Photonic Design Automation Market Breakdown, by Application
  - 11.3.7.6 Switzerland Photonic Design Automation Market Revenue and Forecasts to 2030 (US$ Mn)
    - 11.3.7.6.1 Switzerland Photonic Design Automation Market Breakdown, by Component
    - 11.3.7.6.2 Switzerland Photonic Design Automation Market Breakdown, by Deployment
    - 11.3.7.6.3 Switzerland Photonic Design Automation Market Breakdown, by Organization Size
    - 11.3.7.6.4 Switzerland Photonic Design Automation Market Breakdown, by Application
  - 11.3.7.7 Rest of Europe Photonic Design Automation Market Revenue and Forecasts to 2030 (US$ Mn)
    - 11.3.7.7.1 Rest of Europe Photonic Design Automation Market Breakdown, by Component
    - 11.3.7.7.2 Rest of Europe Photonic Design Automation Market Breakdown, by Deployment
    - 11.3.7.7.3 Rest of Europe Photonic Design Automation Market Breakdown, by Organization Size
    - 11.3.7.7.4 Rest of Europe Photonic Design Automation Market Breakdown, by Application
11.4 APAC
- 11.4.1 APAC Photonic Design Automation Market Overview
- 11.4.2 APAC Photonic Design Automation Market Revenue and Forecasts to 2030 (US$ Mn)
- 11.4.3 APAC Photonic Design Automation Market Breakdown by Component
  - 11.4.3.1 APAC Photonic Design Automation Market Revenue and Forecasts and Analysis - By Component
- 11.4.4 APAC Photonic Design Automation Market Breakdown by Deployment
  - 11.4.4.1 APAC Photonic Design Automation Market Revenue and Forecasts and Analysis - By Deployment
- 11.4.5 APAC Photonic Design Automation Market Breakdown by Organization Size
  - 11.4.5.1 APAC Photonic Design Automation Market Revenue and Forecasts and Analysis - By Organization Size
- 11.4.6 APAC Photonic Design Automation Market Breakdown by Application
  - 11.4.6.1 APAC Photonic Design Automation Market Revenue and Forecasts and Analysis - By Application
- 11.4.7 APAC Photonic Design Automation Market Revenue and Forecasts and Analysis - By Country
  - 11.4.7.1 APAC Photonic Design Automation Market Revenue and Forecasts and Analysis - By Country
  - 11.4.7.2 China Photonic Design Automation Market Revenue and Forecasts to 2030 (US$ Mn)
    - 11.4.7.2.1 China Photonic Design Automation Market Breakdown, by Component
    - 11.4.7.2.2 China Photonic Design Automation Market Breakdown, by Deployment
    - 11.4.7.2.3 China Photonic Design Automation Market Breakdown, by Organization Size
    - 11.4.7.2.4 China Photonic Design Automation Market Breakdown, by Application
  - 11.4.7.3 Japan Photonic Design Automation Market Revenue and Forecasts to 2030 (US$ Mn)
    - 11.4.7.3.1 Japan Photonic Design Automation Market Breakdown, by Component
    - 11.4.7.3.2 Japan Photonic Design Automation Market Breakdown, by Deployment
    - 11.4.7.3.3 Japan Photonic Design Automation Market Breakdown, by Organization Size
    - 11.4.7.3.4 Japan Photonic Design Automation Market Breakdown, by Application
  - 11.4.7.4 South Korea Photonic Design Automation Market Revenue and Forecasts to 2030 (US$ Mn)
    - 11.4.7.4.1 South Korea Photonic Design Automation Market Breakdown, by Component
    - 11.4.7.4.2 South Korea Photonic Design Automation Market Breakdown, by Deployment
    - 11.4.7.4.3 South Korea Photonic Design Automation Market Breakdown, by Organization Size
    - 11.4.7.4.4 South Korea Photonic Design Automation Market Breakdown, by Application
  - 11.4.7.5 Taiwan Photonic Design Automation Market Revenue and Forecasts to 2030 (US$ Mn)
    - 11.4.7.5.1 Taiwan Photonic Design Automation Market Breakdown, by Component
    - 11.4.7.5.2 Taiwan Photonic Design Automation Market Breakdown, by Deployment
    - 11.4.7.5.3 Taiwan Photonic Design Automation Market Breakdown, by Organization Size
    - 11.4.7.5.4 Taiwan Photonic Design Automation Market Breakdown, by Application
  - 11.4.7.6 Rest of APAC Photonic Design Automation Market Revenue and Forecasts to 2030 (US$ Mn)
    - 11.4.7.6.1 Rest of APAC Photonic Design Automation Market Breakdown, by Component
    - 11.4.7.6.2 Rest of APAC Photonic Design Automation Market Breakdown, by Deployment
    - 11.4.7.6.3 Rest of APAC Photonic Design Automation Market Breakdown, by Organization Size
    - 11.4.7.6.4 Rest of APAC Photonic Design Automation Market Breakdown, by Application
11.5 Rest of the World (RoW)
- 11.5.1 RoW Photonic Design Automation Market Overview
- 11.5.2 RoW Photonic Design Automation Market Revenue and Forecasts to 2030 (US$ Mn)
- 11.5.3 RoW Photonic Design Automation Market Breakdown by Component
  - 11.5.3.1 RoW Photonic Design Automation Market Revenue and Forecasts and Analysis - By Component
- 11.5.4 RoW Photonic Design Automation Market Breakdown by Deployment
  - 11.5.4.1 RoW Photonic Design Automation Market Revenue and Forecasts and Analysis - By Deployment
- 11.5.5 RoW Photonic Design Automation Market Breakdown by Organization Size
  - 11.5.5.1 RoW Photonic Design Automation Market Revenue and Forecasts and Analysis - By Organization Size
- 11.5.6 RoW Photonic Design Automation Market Breakdown by Application
  - 11.5.6.1 RoW Photonic Design Automation Market Revenue and Forecasts and Analysis - By Application
- 11.5.7 RoW Photonic Design Automation Market Revenue and Forecasts and Analysis - By Region
  - 11.5.7.1 RoW Photonic Design Automation Market Revenue and Forecasts and Analysis - By Region
  - 11.5.7.2 MEA Photonic Design Automation Market Revenue and Forecasts to 2030 (US$ Mn)
    - 11.5.7.2.1 MEA Photonic Design Automation Market Breakdown, by Component
    - 11.5.7.2.2 MEA Photonic Design Automation Market Breakdown, by Deployment
    - 11.5.7.2.3 MEA Photonic Design Automation Market Breakdown, by Organization Size
    - 11.5.7.2.4 MEA Photonic Design Automation Market Breakdown, by Application
  - 11.5.7.3 SAM Photonic Design Automation Market Revenue and Forecasts to 2030 (US$ Mn)
    - 11.5.7.3.1 SAM Photonic Design Automation Market Breakdown, by Component
    - 11.5.7.3.2 SAM Photonic Design Automation Market Breakdown, by Deployment
    - 11.5.7.3.3 SAM Photonic Design Automation Market Breakdown, by Organization Size
    - 11.5.7.3.4 SAM Photonic Design Automation Market Breakdown, by Application

12. Photonic Design Automation Market - Impact of COVID-19 Pandemic

12.1 Pre & Post Covid-19 Impact

13. Competitive Landscape

13.1 Heat Map Analysis By Key Players
13.2 Company Positioning & Concentration

14. Industry Landscape

14.1 Overview
14.2 Market Initiative
14.2 New Product Development
14.3 Merger and Acquisition

15. Company Profiles

15.1 Ansys Inc
- 15.1.1 Key Facts
- 15.1.2 Business Description
- 15.1.3 Products and Services
- 15.1.4 Financial Overview
- 15.1.5 SWOT Analysis
- 15.1.6 Key Developments
15.2 LioniX International BV
- 15.2.1 Key Facts
- 15.2.2 Business Description
- 15.2.3 Products and Services
- 15.2.4 Financial Overview
- 15.2.5 SWOT Analysis
- 15.2.6 Key Developments
15.3 VPlphotonics GmbH
- 15.3.1 Key Facts
- 15.3.2 Business Description
- 15.3.3 Products and Services
- 15.3.4 Financial Overview
- 15.3.5 SWOT Analysis
- 15.3.6 Key Developments
15.4 Optiwave Systems Inc
- 15.4.1 Key Facts
- 15.4.2 Business Description
- 15.4.3 Products and Services
- 15.4.4 Financial Overview
- 15.4.5 SWOT Analysis
- 15.4.6 Key Developments
15.5 Luceda Photonics
- 15.5.1 Key Facts
- 15.5.2 Business Description
- 15.5.3 Products and Services
- 15.5.4 Financial Overview
- 15.5.5 SWOT Analysis
- 15.5.6 Key Developments
15.6 Cadence Design Systems Inc
- 15.6.1 Key Facts
- 15.6.2 Business Description
- 15.6.3 Products and Services
- 15.6.4 Financial Overview
- 15.6.5 SWOT Analysis
- 15.6.6 Key Developments
15.7 Siemens AG
- 15.7.1 Key Facts
- 15.7.2 Business Description
- 15.7.3 Products and Services
- 15.7.4 Financial Overview
- 15.7.5 SWOT Analysis
- 15.7.6 Key Developments
15.8 Synopsys Inc
- 15.8.1 Key Facts
- 15.8.2 Business Description
- 15.8.3 Products and Services
- 15.8.4 Financial Overview
- 15.8.5 SWOT Analysis
- 15.8.6 Key Developments
15.9 AIM Photonics Inc
- 15.9.1 Key Facts
- 15.9.2 Business Description
- 15.9.3 Products and Services
- 15.9.4 Financial Overview
- 15.9.5 SWOT Analysis
- 15.9.6 Key Developments
15.10 SystemLab Inc
- 15.10.1 Key Facts
- 15.10.2 Business Description
- 15.10.3 Products and Services
- 15.10.4 Financial Overview
- 15.10.5 SWOT Analysis
- 15.10.6 Key Developments

16. Appendix

16.1 Word Index