Wafer-level Test and Burn-in [WLTBI] Market

Wafer-level Test and Burn-in [WLTBI] Market (Type: Single Wafer and Multi and Full Wafer; and Application: IDMs and OSAT) - Global Industry Analysis, Size, Share, Growth, Trends, and Forecast, 2021-2031

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Semiconductors Used in Variety of Applications Drives Wafer-level Test and Burn-in (WLTBI) Market

Wafer-level test and burn-in (WLTBI) introduces the means of subjecting semiconductor devices to electrical testing and burn-in while in wafer form. Burn-in is a stress test for temperature reliability used for detection and screening of potential errors in the early phase. The process works by employing a wafer prober to provide the necessary electrical excitation to all the blocks on the die of the wafer through numerous ultrathin probing needles that land on contact pads, ball grid arrays, or bumps on the die. On the contrary, the desired temperature of the die is obtained by the wafer prober through a built-in hot plate that elevates the temperature of the wafer to the required junction temperature.

The applications of WLTBI are important in several industries, especially in integrated device manufacturers and outsourced assembly and test companies. Moreover, the WLTBI applies to machines sold as a bare die, wafer-level packaged tools, and devices that are designed for conventional packaging. Moreover, the use of semiconductors in electronic systems and parts of automobiles such as infotainment, engine control, and safety features has been increased and is further expected to grow in demand. The current increased demand for semiconductors and the growing application of WLTBI are likely to boost the global wafer-level test and burn-in (WLTBI) market during the forecast period.

Slowdown in Semiconductor Industry Impacts WLTBI Market During COVID-19 Crisis

The COVID-19 pandemic has impacted various fundamental sectors that include customer behavior, business revenues, and numerous aspects of corporate operations. Many organizations are struggling with unclear future decisions, some of whom may face severe losses in the crisis. However, businesses are in a dire need of government interventions and other variables depending on the industry type and tax leverages. There is a massive impact on the wafer-level test and burn-in (WLTBI) market due to the heavy effects of COVID-19 on semiconductors, automobiles, and the consumer electronics industry.

Semiconductor companies that are major consumers of the WLTBI have made a strategic decision in favor of protecting employees, securing supply chains, and addressing other pressing concerns. This has resulted in a halt on production activities. In addition, various governments continue to impose physical-distancing requirements and limited production activities to help fight the spread of harmful coronavirus. This expects to hinder the ongoing growth rate till the pandemic is over. However, key leading companies are preparing for the opportunities for when the pandemic abates and the next normal begins. The pandemic situation is expected to improve shortly, opening markets and production, and the wafer-level test and burn-in (WLTBI) market is anticipated to grow during the projected period.

WFTBI in High Demand for Electronic Systems, Automobiles Parts

The semiconductor industry is necessary for all the sectors to provide products with increased functionality at a low cost. The increasing demand for known good die (KGD), including a variety of Systems in a Package, Multi-Chip Modules, and stacked memories, highlights the significance of cost-effective and viable WLTBI solutions. The wafer-level burn-in technology needs a single alignment step and a single dimensionally stable fixture to burn numbers of ICs concurrently. This approach can be cost-effective as compared to numerous precision die carriers. Moreover, semiconductor devices can be tested on exposed wafers without the necessity to cut the wafer into devices and package them. Ultrathin probing needles are used to communicate with contact pads on the die and to supply the required electrical excitation to the die under test. All these factors are contributing to the expansion of the wafer-level test and burn-in (WLTBI) market.

Burn-in for KGDs at the wafer-level needs very few test insertions and further decreases the burn-in cycle time when confronted with die-level burn-in. Furthermore, WLTBI allows quick feedback to wafer manufacturing, which presents an efficient mechanism for process administration and improving the yield of the process simultaneously. The wafer-level test and burn-in have proven to be a comparatively low-cost technique for manufacturing reliable and fully functional known good die, which is a major factor for driving the wafer-level test and burn-in (WLTBI) market. With advancements of products and growing need, commercial WLTBI test equipment is now being expanded by some major semiconductor companies to lower manufacturing costs. Furthermore, the use of semiconductors has significantly grown in electronic systems and parts of automobiles such as infotainment, engine control, and safety features. Compound semiconductors that are mostly used in autonomous and self-driving cars require 100% burn-in due to natural material properties. All these factors are contributing to the growth of the wafer-level test and burn-in (WLTBI) market during the forecast period.

Asia Pacific to Dominate Wafer-level Test and Burn-in (WLTBI) Market

With development and advancement in technology, the need for semiconductors is increasing. Various innovations in technical devices were possible with semiconductor materials. Such devices are growing in popularity in several applications due to their compactness, reliability, power efficiency, and low cost. From transistors to LED displays, the need for semiconductors is growing in the day-to-day life, and with increasing human dependence on electronics, the need for wafer-level tests and burn-in will be crucial in semiconductors. The application of WLTBI in the microprocessors now allows control over trains, cars, and extends to space vehicles. Thus, as the need for semiconductors is tremendously increasing, the global wafer-level test and burn-in (WLTBI) market is expected to reach US$ 5.6 Bn by 2031, expanding at a CAGR of ~4% during the forecast period.

The presence of several wafer foundry companies in Asian countries such as Taiwan, South Korea, Japan, and China is anticipated to drive the wafer-level test and burn-in (WLTBI) market in Asia Pacific. As many major leading businesses choose to outsource the fabrication of their hardware to dedicated manufacturing firms, the wafer-level test and burn-in (WLTBI) market is expected to witness major demands from the Asia Pacific. There is a heavy demand for consumer electronics and automobiles industry in North America. Thus, the North America wafer-level test and burn-in (WLTBI) market is expected to grow during the projected period.

Analysts’ Viewpoint

The heavy demand for wafer-level test and burn-in (WLTBI) market is anticipated from various industries for high reliability and low cost once manufacturers start working in a full capacity post the COVID-19 crisis in 2021. However, regular maintenance required to avoid failure of contact between probes is anticipated to hinder the growth of the wafer-level test and burn-in (WLTBI) market during the projected period. Nevertheless, the advancement in technology is allowing manufacturers to overcome any technical challenges. Moreover, the growing use of semiconductors in telecom and automobile industries is contributing to the global wafer-level test and burn-in (WLTBI) market growth.

Wafer-level Test and Burn-in (WLTBI) Market: Overview

According to Transparency Market Research’s latest research report on the global wafer-level test and burn-in (WLTBI) market for the historical period of 2017–2019 and the forecast period of 2021–2031, increasing usage of wafer-level test and burn-in (WLTBI) in the semiconductor industry across the globe is a major factor expected to boost the global wafer-level test and burn-in (WLTBI) market during the forecast period
In terms of revenue, the global wafer-level test and burn-in (WLTBI) market is estimated to exceed the value of US$ 5.6 Bn by 2031, expanding at a CAGR of ~4% during the forecast period

Increasing Usage of Semiconductors in Automotive and Telecom Sectors: A Key Driver of Wafer-level Test and Burn-in (WLTBI) Market

Semiconductors are increasingly being used in electronic systems and parts of automobiles such as infotainment, engine control, and safety features. Compound semiconductors, which are used in autonomous and self-driving cars, require 100% burn-in due to natural material properties.
Moreover, semiconductors are being used increasingly in the telecom industry, such as silicon photonics devices for data centers and 5G infrastructure, fiber optic transceivers, and mobile communication systems. These factors are propelling the wafer-level test and burn-in (WLTBI) market.
For instance, Aehr Test Systems’ wafer parks with FOX-XP multi-wafer test and burn-in systems have been in production and qualified by automotive suppliers for full wafer test of silicon carbide power devices since 2020, which are used in electric and hybrid electric vehicle power trains
Some manufacturers have already introduced new advance technologies in wafer-level test and burn-in (WLTBI) for benefits that include reduction in process steps when compared to packaged level and die level burn-in, reduction of wafer test insertion and probe time, and faster test result feedback to the fab. These benefits over other methods such as die level burn-in are fueling market growth.
As a result, demand for wafer-level test and burn-in (WLTBI) is significantly high, which is expected to drive the global wafer-level test and burn-in (WLTBI) market during the forecast period
However, regular maintenance required to avoid failure of contact between probes is anticipated to limit the growth of the wafer-level test and burn-in (WLTBI) market during the forecast period from 2021 to 2031. Even if a single probe fails to contact, it causes a test or burn-in to fail, which is expected to restrain the growth of the global wafer-level test and burn-in (WLTBI) market.

Benefits Offered by Wafer-level Test and Burn-in (WLTBI)

Various benefits of wafer-level test and burn-in include lower cost as compared to die level burn-in. Depending on the packaging cost, wafer yields, and other considerations, IC manufacturers find this method economical.
Advantages, such as low cost, reliability, and simplicity, have increased the attractiveness of wafer-level test and burn-in the market. In addition, the wafer level burn-in technology requires a single alignment step and a single dimensionally stable fixture to burn in hundreds of ICs simultaneously. This approach is much cheaper than using hundreds of precision die carriers.
Thus, significant benefits of wafer level burn-in systems in achieving high-performance efficiencies is projected to have a positive impact on the global wafer-level test and burn-in (WLTBI) market during the forecast period

Wafer-level Test and Burn-in (WLTBI) Market: Competition Landscape

Detailed profiles of providers of wafer-level test and burn-in (WLTBI) have been provided in the report to evaluate their financials, key product offerings, recent developments, and strategies
Key players operating in the global wafer-level test and burn-in (WLTBI) market are
- Aehr Test Systems
- Delta V Instruments Inc.
- Amkor Technology
- Robson Technologies, Inc.
- Teradyne Inc.
- Abrel Products Ltd
- Electron Test Equipment Limited
- Pentamaster
- Advantest Corporation

Wafer-level Test and Burn-in (WLTBI) Market: Key Developments

Key providers of wafer-level test and burn-in (WLTBI) such as Emerson Electric Co., Honeywell International Inc., PCB Piezotronics Inc., Amphenol Corporation, Setra Systems, Inc., ABB Ltd., IFM electronic GmbH, KistlerInstrument Corp., Schneider Electric S.E., Siemens AG, Wika Group, TE Connectivity, and Yokogawa Electric Corporation are focusing on designing cost-effective wafer-level test and burn-in (WLTBI) to attract more customers. Some other key developments in the global wafer-level test and burn-in (WLTBI) market are highlighted below:
- In March 2021, Aehr Test Systems received an order for multiple WaferPak™ Contactors from one of its lead FOX-XP full wafer test and burn-in system customers for their installed base of FOX multi-wafer test systems for US$ 1.2 Mn
- In February 2021, Amkor Technology achieved Industry 4.0 initiatives and extended its leadership in quality and efficiency excellence. The company is extensively focusing on advanced packaging technologies.
- In October 2020, Pentamaster discovered new burn-in test solutions for power devices with a user-definable burn-in profile. This newly discovered silicon carbide burn-in test solution is specially designed to define the limits of power devices at wafer and module level.
- In May 2017, Amkor Technology Inc. signed a strategic long-term agreement worth US$ 145 Bn with IBM for semiconductor assembly and test services. As a part of this agreement, Amkor Technology Inc. will acquire IBM’s Singapore test operations, including testers, related assets, and employees.
- Delta V Instruments Inc. manufactures package level burn-in systems, including TSE BOSS Test Systems™, wafer level burn-in systems, custom systems, test fixtures, and burn-in test services. The company’s wafer level burn-in test system is used to perform process control feedback by running test wafers along with the production run.
In the global wafer-level test and burn-in (WLTBI) market report, we have discussed individual strategies, followed by company profiles of providers of wafer-level test and burn-in (WLTBI). The ‘Competition Landscape’ section has been included in the report to provide readers with a dashboard view and company market share analysis of key players operating in the global wafer-level test and burn-in (WLTBI) market.

1. Global Wafer-level Test and Burn-in (WLTBI) Market - Executive Summary

1.1. Global Wafer-level Test and Burn-in (WLTBI) Market Country Analysis

1.2. Competition Blueprint

1.3. Technology Time Line Mapping

1.4. TMR Analysis and Recommendations

2. Market Overview

2.1. Market Introduction

2.2. Market Definition

2.3. Market Taxonomy

3. Market Dynamics

3.1. Macroeconomic Factors

3.2. Drivers

3.2.1. Economic Drivers

3.2.2. Supply Side Drivers

3.2.3. Demand Side Drivers

3.3. Market Restraints

3.4. Market Trends

3.5. Trend Analysis- Impact on Time Line (2021-2031)

3.6. Key Regulations By Regions

4. Associated Industry and Key Indicator Assessment

4.1. Parent Industry Overview

4.2. Supply Chain Analysis

4.2.1. Profitability and Gross Margin Analysis By Competition

4.2.2. List of Active Participants- By Region

4.2.2.1. Raw Material Suppliers

4.2.2.2. Key Manufacturers

4.2.2.3. Integrators

4.2.2.4. Key Distributor/Retailers

4.3. Technology Roadmap Analysis

4.4. Porter Five Forces Analysis

5. Global Wafer-level Test and Burn-in (WLTBI) Market Analysis and Forecast

5.1. Market Size Analysis (2017-2019) and Forecast (2021-2031)

5.1.1. Market Value (US$ Mn) and Y-o-Y Growth

5.2. Global Wafer-level Test and Burn-in (WLTBI) Market Scenario Forecast (Optimistic, Likely, and Conservative Market Conditions)

5.2.1. Forecast Factors and Relevance of Impact

5.2.2. Regional Wafer-level Test and Burn-in (WLTBI) Market Business Performance Summary

6. Global Wafer-level Test and Burn-in (WLTBI) Market Analysis By Type

6.1. Introduction

6.1.1. Y-o-Y Growth Comparison By Type

6.2. Wafer-level Test and Burn-in (WLTBI) Market Size (US$ Mn) Analysis & Forecast, By Type, 2017 - 2031

6.2.1. Single Wafer

6.2.2. Multi and Full Wafer

6.3. Market Attractiveness Analysis By Type

7. Global Wafer-level Test and Burn-in (WLTBI) Market Analysis By Application

7.1. Introduction

7.1.1. Y-o-Y Growth Comparison By Application

7.2. Wafer-level Test and Burn-in (WLTBI) Market Size (US$ Mn) Analysis & Forecast, By Application, 2017 - 2031

7.2.1. IDMs

7.2.2. OSAT

7.3. Market Attractiveness Analysis By Application

8. Global Wafer-level Test and Burn-in (WLTBI) Market Analysis and Forecast, By Region

8.1. Introduction

8.1.1. Basis Point Share (BPS) Analysis By Region

8.2. Wafer-level Test and Burn-in (WLTBI) Market Size (US$ Mn) Analysis & Forecast, By Region, 2017 - 2031

8.2.1. North America

8.2.2. Europe

8.2.3. Asia Pacific

8.2.4. Middle East & Africa

8.2.5. South America

8.3. Market Attractiveness Analysis By Region

9. North America Wafer-level Test and Burn-in (WLTBI) Market Analysis and Forecast

9.1. Introduction

9.2. Drivers and Restraints: Impact Analysis

9.3. Wafer-level Test and Burn-in (WLTBI) Market Size (US$ Mn) Analysis & Forecast, By Type, 2017 - 2031

9.3.1. Single Wafer

9.3.2. Multi and Full Wafer

9.4. Wafer-level Test and Burn-in (WLTBI) Market Size (US$ Mn) Analysis & Forecast, By Application, 2017 - 2031

9.4.1. IDMs

9.4.2. OSAT

9.5. Wafer-level Test and Burn-in (WLTBI) Market Size (US$ Mn) Analysis & Forecast, By Country, 2017 - 2031

9.5.1. U.S.

9.5.2. Canada

9.5.3. Mexico

9.6. Market Attractiveness Analysis

9.6.1. Type

9.6.2. Application

9.6.3. Country

10. Europe Wafer-level Test and Burn-in (WLTBI) Market Analysis and Forecast

10.1. Introduction

10.2. Drivers and Restraints: Impact Analysis

10.3. Wafer-level Test and Burn-in (WLTBI) Market Size (US$ Mn) Analysis & Forecast, By Type, 2017 - 2031

10.3.1. Single Wafer

10.3.2. Multi and Full Wafer

10.4. Wafer-level Test and Burn-in (WLTBI) Market Size (US$ Mn) Analysis & Forecast, By Application, 2017 - 2031

10.4.1. IDMs

10.4.2. OSAT

10.5. Wafer-level Test and Burn-in (WLTBI) Market Size (US$ Mn) Analysis & Forecast, By Country & Sub-region, 2017 - 2031

10.5.1. U.K.

10.5.2. Germany

10.5.3. France

10.5.4. Italy

10.5.5. Russia

10.5.6. Rest of Europe

10.6. Market Attractiveness Analysis

10.6.1. Type

10.6.2. Application

10.6.3. Country

11. Asia Pacific Wafer-level Test and Burn-in (WLTBI) Market Analysis and Forecast

11.1. Introduction

11.2. Drivers and Restraints: Impact Analysis

11.3. Wafer-level Test and Burn-in (WLTBI) Market Size (US$ Mn) Analysis & Forecast, By Type, 2017 - 2031

11.3.1. Single Wafer

11.3.2. Multi and Full Wafer

11.4. Wafer-level Test and Burn-in (WLTBI) Market Size (US$ Mn) Analysis & Forecast, By Application, 2017 - 2031

11.4.1. IDMs

11.4.2. OSAT

11.5. Wafer-level Test and Burn-in (WLTBI) Market Size (US$ Mn) Analysis & Forecast, By Country & Sub-region, 2017 - 2031

11.5.1. China

11.5.2. India

11.5.3. Japan

11.5.4. South Korea

11.5.5. ASEAN

11.5.6. Rest of Asia Pacific

11.6. Market Attractiveness Analysis

11.6.1. Type

11.6.2. Application

11.6.3. Country

12. Middle East & Africa (MEA) Wafer-level Test and Burn-in (WLTBI) Market Analysis and Forecast

12.1. Introduction

12.2. Drivers and Restraints: Impact Analysis

12.3. Wafer-level Test and Burn-in (WLTBI) Market Size (US$ Mn) Analysis & Forecast, By Type, 2017 - 2031

12.3.1. Single Wafer

12.3.2. Multi and Full Wafer

12.4. Wafer-level Test and Burn-in (WLTBI) Market Size (US$ Mn) Analysis & Forecast, By Application, 2017 - 2031

12.4.1. IDMs

12.4.2. OSAT

12.5. Wafer-level Test and Burn-in (WLTBI) Market Size (US$ Mn) Analysis & Forecast, By Country & Sub-region, 2017 - 2031

12.5.1. GCC

12.5.2. South Africa

12.5.3. North Africa

12.5.4. Rest of Middle East & Africa

12.6. Market Attractiveness Analysis

12.6.1. Type

12.6.2. Application

12.6.3. Country

13. South America Wafer-level Test and Burn-in (WLTBI) Market Analysis and Forecast

13.1. Introduction

13.2. Drivers and Restraints: Impact Analysis

13.3. Wafer-level Test and Burn-in (WLTBI) Market Size (US$ Mn) Analysis & Forecast, By Type, 2017 - 2031

13.3.1. Single Wafer

13.3.2. Multi and Full Wafer

13.4. Wafer-level Test and Burn-in (WLTBI) Market Size (US$ Mn) Analysis & Forecast, By Application, 2017 - 2031

13.4.1. IDMs

13.4.2. OSAT

13.5. Wafer-level Test and Burn-in (WLTBI) Market Size (US$ Mn) Analysis & Forecast, By Country & Sub-region, 2017 - 2031

13.5.1. Brazil

13.5.2. Argentina

13.5.3. Rest of South America

13.6. Market Attractiveness Analysis

13.6.1. Type

13.6.2. Application

13.6.3. Country

14. Competition Assessment

14.1. Global Wafer-level Test and Burn-in (WLTBI) Market Competition - a Dashboard View

14.2. Global Wafer-level Test and Burn-in (WLTBI) Market Structure Analysis

14.3. Global Wafer-level Test and Burn-in (WLTBI) Market Company Share Analysis, by Value and Volume (2020)

14.4. Key Participants Market Presence (Intensity Mapping) by Region

15. Competition Deep-dive (Manufacturers/Suppliers)

15.1. Aehr Test Systems

15.1.1. Overview

15.1.2. Product Portfolio

15.1.3. Sales Footprint

15.1.4. Channel Footprint

15.1.4.1. Distributors List

15.1.5. Strategy Overview

15.1.5.1. Marketing Strategy

15.1.5.2. Culture Strategy

15.1.5.3. Channel Strategy

15.1.6. SWOT Analysis

15.1.7. Financial Analysis

15.1.8. Revenue Share

15.1.8.1. By Region

15.1.9. Key Clients

15.1.10. Analyst Comments

15.2. Pentamaster

15.2.1. Overview

15.2.2. Product Portfolio

15.2.3. Sales Footprint

15.2.4. Channel Footprint

15.2.4.1. Distributors List

15.2.5. Strategy Overview

15.2.5.1. Marketing Strategy

15.2.5.2. Culture Strategy

15.2.5.3. Channel Strategy

15.2.6. SWOT Analysis

15.2.7. Financial Analysis

15.2.8. Revenue Share

15.2.8.1. By Region

15.2.9. Key Clients

15.2.10. Analyst Comments

15.3. Delta V Instruments Inc.

15.3.1. Overview

15.3.2. Product Portfolio

15.3.3. Sales Footprint

15.3.4. Channel Footprint

15.3.4.1. Distributors List

15.3.5. Strategy Overview

15.3.5.1. Marketing Strategy

15.3.5.2. Culture Strategy

15.3.5.3. Channel Strategy

15.3.6. SWOT Analysis

15.3.7. Financial Analysis

15.3.8. Revenue Share

15.3.8.1. By Region

15.3.9. Key Clients

15.3.10. Analyst Comments

15.4. Electron Test Equipment Limited

15.4.1. Overview

15.4.2. Product Portfolio

15.4.3. Sales Footprint

15.4.4. Channel Footprint

15.4.4.1. Distributors List

15.4.5. Strategy Overview

15.4.5.1. Marketing Strategy

15.4.5.2. Culture Strategy

15.4.5.3. Channel Strategy

15.4.6. SWOT Analysis

15.4.7. Financial Analysis

15.4.8. Revenue Share

15.4.8.1. By Region

15.4.9. Key Clients

15.4.10. Analyst Comments

15.5. Amkor Technology

15.5.1. Overview

15.5.2. Product Portfolio

15.5.3. Sales Footprint

15.5.4. Channel Footprint

15.5.4.1. Distributors List

15.5.5. Strategy Overview

15.5.5.1. Marketing Strategy

15.5.5.2. Culture Strategy

15.5.5.3. Channel Strategy

15.5.6. SWOT Analysis

15.5.7. Financial Analysis

15.5.8. Revenue Share

15.5.8.1. By Region

15.5.9. Key Clients

15.5.10. Analyst Comments

15.6. Advantest Corporation

15.6.1. Overview

15.6.2. Product Portfolio

15.6.3. Sales Footprint

15.6.4. Channel Footprint

15.6.4.1. Distributors List

15.6.5. Strategy Overview

15.6.5.1. Marketing Strategy

15.6.5.2. Culture Strategy

15.6.5.3. Channel Strategy

15.6.6. SWOT Analysis

15.6.7. Financial Analysis

15.6.8. Revenue Share

15.6.8.1. By Region

15.6.9. Key Clients

15.6.10. Analyst Comments

15.7. Abrel Products Ltd.

15.7.1. Overview

15.7.2. Product Portfolio

15.7.3. Sales Footprint

15.7.4. Channel Footprint

15.7.4.1. Distributors List

15.7.5. Strategy Overview

15.7.5.1. Marketing Strategy

15.7.5.2. Culture Strategy

15.7.5.3. Channel Strategy

15.7.6. SWOT Analysis

15.7.7. Financial Analysis

15.7.8. Revenue Share

15.7.8.1. By Region

15.7.9. Key Clients

15.7.10. Analyst Comments

15.8. Robson Technologies, Inc.

15.8.1. Overview

15.8.2. Product Portfolio

15.8.3. Sales Footprint

15.8.4. Channel Footprint

15.8.4.1. Distributors List

15.8.5. Strategy Overview

15.8.5.1. Marketing Strategy

15.8.5.2. Culture Strategy

15.8.5.3. Channel Strategy

15.8.6. SWOT Analysis

15.8.7. Financial Analysis

15.8.8. Revenue Share

15.8.8.1. By Region

15.8.9. Key Clients

15.8.10. Analyst Comments

15.9. Teradyne Inc.

15.9.1. Overview

15.9.2. Product Portfolio

15.9.3. Sales Footprint

15.9.4. Channel Footprint

15.9.4.1. Distributors List

15.9.5. Strategy Overview

15.9.5.1. Marketing Strategy

15.9.5.2. Culture Strategy

15.9.5.3. Channel Strategy

15.9.6. SWOT Analysis

15.9.7. Financial Analysis

15.9.8. Revenue Share

15.9.8.1. By Region

15.9.9. Key Clients

15.9.10. Analyst Comments

15.10. Others (On additional request)

16. Recommendation- Critical Success Factors

17. Research Methodology

18. Assumptions & Acronyms Used

List of Table

Table 01: Global Wafer-level Test and Burn-in (WLTBI) Market Revenue (US$ Mn), By Type, 2017–2031

Table 02: Global Wafer-level Test and Burn-in (WLTBI) Market Revenue (US$ Mn), By Applications , 2017–2031

Table 03: Global Wafer-level Test and Burn-in (WLTBI) Market Revenue (US$ Mn), by Region, 2017–2031

Table 04: North America Wafer-level Test and Burn-in (WLTBI) Market Revenue (US$ Mn), By Type, 2017–2031

Table 05: North America Wafer-level Test and Burn-in (WLTBI) Market Revenue (US$ Mn), By Applications, 2017–2031

Table 06: North America Wafer-level Test and Burn-in (WLTBI) Market Revenue (US$ Mn), by Country, 2017–2031

Table 07: Europe Wafer-level Test and Burn-in (WLTBI) Market Revenue (US$ Mn), By Type, 2017–2031

Table 08: Europe Wafer-level Test and Burn-in (WLTBI) Market Revenue (US$ Mn), By Applications, 2017–2031

Table 09: Europe Wafer-level Test and Burn-in (WLTBI) Market Revenue (US$ Mn), by Country, 2017–2031

Table 10: Asia Pacific Wafer-level Test and Burn-in (WLTBI) Market Revenue (US$ Mn), By Type, 2017–2031

Table 11: Asia Pacific Wafer-level Test and Burn-in (WLTBI) Market Revenue (US$ Mn), By Applications, 2017–2031

Table 12: Asia Pacific Wafer-level Test and Burn-in (WLTBI) Market Revenue (US$ Mn), by Country, 2017–2031

Table 13: Middle East & Africa (MEA) Wafer-level Test and Burn-in (WLTBI) Market Revenue (US$ Mn), By Type, 2017–2031

Table 14: Middle East & Africa (MEA) Wafer-level Test and Burn-in (WLTBI) Market Revenue (US$ Mn), By Applications, 2017–2031

Table 15: Middle East & Africa (MEA) Wafer-level Test and Burn-in (WLTBI) Market Revenue (US$ Mn), by Country, 2017–2031

Table 16: South America Wafer-level Test and Burn-in (WLTBI) Market Revenue (US$ Mn), By Type, 2017–2031

Table 17: South America Wafer-level Test and Burn-in (WLTBI) Market Revenue (US$ Mn), By Applications, 2017–2031

Table 18: South America Wafer-level Test and Burn-in (WLTBI) Market Revenue (US$ Mn), by Country, 2017–2031

List of Figure

Figure 01: Global Wafer-level Test and Burn-in (WLTBI) Market Value (USD Mn) Forecast, 2021–2031

Figure 02: Global Wafer-level Test and Burn-in (WLTBI) Market Size Analysis (2017-2019) and Forecast (2021-2031)

Figure 03: Global Wafer-level Test and Burn-in (WLTBI) Market, by Single Wafer

Figure 04: Global Wafer-level Test and Burn-in (WLTBI) Market, by Multi and Full Wafer

Figure 05: Global Wafer-level Test and Burn-in (WLTBI) Market Comparison Matrix, By Type

Figure 06: Global Wafer-level Test and Burn-in (WLTBI) Market Attractiveness Analysis, By Type

Figure 07: Global Wafer-level Test and Burn-in (WLTBI) Market, by IDMs

Figure 08: Global Wafer-level Test and Burn-in (WLTBI) Market, by OSAT

Figure 09: Global Wafer-level Test and Burn-in (WLTBI) Market Comparison Matrix, By Applications

Figure 10: Global Wafer-level Test and Burn-in (WLTBI) Market Attractiveness Analysis, By Applications

Figure 11: Global Wafer-level Test and Burn-in (WLTBI) Market Value Share Analysis, by Region (2021E)

Figure 12: Global Wafer-level Test and Burn-in (WLTBI) Market Value Share Analysis, by Region (2031F)

Figure 13: Global Wafer-level Test and Burn-in (WLTBI) Market Attractiveness Analysis, by Region

Figure 14: North America Wafer-level Test and Burn-in (WLTBI) Market Revenue Projection and Y–O–Y Growth, 2017-2031 (US$ Mn and %)

Figure 15: North America Wafer-level Test and Burn-in (WLTBI) Market Value Share Analysis, By Type (2021)

Figure 16: North America Wafer-level Test and Burn-in (WLTBI) Market Value Share Analysis, By Type (2031)

Figure 17: North America Wafer-level Test and Burn-in (WLTBI) Market Value Share Analysis, By Applications (2021)

Figure 18: North America Wafer-level Test and Burn-in (WLTBI) Market Value Share Analysis, By Applications (2031)

Figure 19: North America Wafer-level Test and Burn-in (WLTBI) Market Value Share Analysis, by Country (2021)

Figure 20: North America Wafer-level Test and Burn-in (WLTBI) Market Value Share Analysis, by Country (2031)

Figure 21: North America Wafer-level Test and Burn-in (WLTBI) Market Attractiveness Analysis, By Type

Figure 22: North America Wafer-level Test and Burn-in (WLTBI) Market Attractiveness Analysis, By Applications

Figure 23: North America Wafer-level Test and Burn-in (WLTBI) Market Attractiveness Analysis, by Country

Figure 24: Europe Wafer-level Test and Burn-in (WLTBI) Market Revenue Projection and Y–O–Y Growth, 2017-2031 (US$ Mn and %)

Figure 25: Europe Wafer-level Test and Burn-in (WLTBI) Market Value Share Analysis, By Type (2021)

Figure 26: Europe Wafer-level Test and Burn-in (WLTBI) Market Value Share Analysis, By Type (2031)

Figure 27: Europe Wafer-level Test and Burn-in (WLTBI) Market Value Share Analysis, By Applications (2021)

Figure 28: Europe Wafer-level Test and Burn-in (WLTBI) Market Value Share Analysis, By Applications (2031)

Figure 29: Europe Wafer-level Test and Burn-in (WLTBI) Market Value Share Analysis, by Country (2021)

Figure 30: Europe Wafer-level Test and Burn-in (WLTBI) Market Value Share Analysis, by Country (2031)

Figure 31: Europe Wafer-level Test and Burn-in (WLTBI) Market Attractiveness Analysis, By Type

Figure 32: Europe Wafer-level Test and Burn-in (WLTBI) Market Attractiveness Analysis, By Applications

Figure 33: Europe Wafer-level Test and Burn-in (WLTBI) Market Attractiveness Analysis, by Country

Figure 34: Asia Pacific Wafer-level Test and Burn-in (WLTBI) Market Revenue Projection and Y–O–Y Growth, 2017-2031 (US$ Mn and %)

Figure 35: Asia Pacific Wafer-level Test and Burn-in (WLTBI) Market Value Share Analysis, By Type (2021)

Figure 36: Asia Pacific Wafer-level Test and Burn-in (WLTBI) Market Value Share Analysis, By Type (2031)

Figure 37: Asia Pacific Wafer-level Test and Burn-in (WLTBI) Market Value Share Analysis, By Applications (2021)

Figure 38: Asia Pacific Wafer-level Test and Burn-in (WLTBI) Market Value Share Analysis, By Applications (2031)

Figure 39: Asia Pacific Wafer-level Test and Burn-in (WLTBI) Market Value Share Analysis, by Country (2021)

Figure 40: Asia Pacific Wafer-level Test and Burn-in (WLTBI) Market Value Share Analysis, by Country (2031)

Figure 41: Asia Pacific Wafer-level Test and Burn-in (WLTBI) Market Attractiveness Analysis, By Type

Figure 42: Asia Pacific Wafer-level Test and Burn-in (WLTBI) Market Attractiveness Analysis, By Applications

Figure 43: Asia Pacific Wafer-level Test and Burn-in (WLTBI) Market Attractiveness Analysis, by Country

Figure 44: Middle East & Africa (MEA) Wafer-level Test and Burn-in (WLTBI) Market Revenue Projection and Y–O–Y Growth, 2017-2031 (US$ Mn and %)

Figure 45: Middle East & Africa (MEA) Wafer-level Test and Burn-in (WLTBI) Market Value Share Analysis, By Type (2021)

Figure 46: Middle East & Africa (MEA) Wafer-level Test and Burn-in (WLTBI) Market Value Share Analysis, By Type (2031)

Figure 47: Middle East & Africa (MEA) Wafer-level Test and Burn-in (WLTBI) Market Value Share Analysis, By Applications (2021)

Figure 48: Middle East & Africa (MEA) Wafer-level Test and Burn-in (WLTBI) Market Value Share Analysis, By Applications (2031)

Figure 49: Middle East & Africa (MEA) Wafer-level Test and Burn-in (WLTBI) Market Value Share Analysis, by Country (2021)

Figure 50: Middle East & Africa (MEA) Wafer-level Test and Burn-in (WLTBI) Market Value Share Analysis, by Country (2031)

Figure 51: Middle East & Africa (MEA) Wafer-level Test and Burn-in (WLTBI) Market Attractiveness Analysis, By Type

Figure 52: Middle East & Africa (MEA) Wafer-level Test and Burn-in (WLTBI) Market Attractiveness Analysis, By Applications

Figure 53: Middle East & Africa (MEA) Wafer-level Test and Burn-in (WLTBI) Market Attractiveness Analysis, by Country

Figure 54: South America Wafer-level Test and Burn-in (WLTBI) Market Revenue Projection and Y–O–Y Growth, 2017-2031 (US$ Mn and %)

Figure 55: South America Wafer-level Test and Burn-in (WLTBI) Market Value Share Analysis, By Type (2021)

Figure 56: South America Wafer-level Test and Burn-in (WLTBI) Market Value Share Analysis, By Type (2031)

Figure 57: South America Wafer-level Test and Burn-in (WLTBI) Market Value Share Analysis, By Applications (2021)

Figure 58: South America Wafer-level Test and Burn-in (WLTBI) Market Value Share Analysis, By Applications (2031)

Figure 59: South America Wafer-level Test and Burn-in (WLTBI) Market Value Share Analysis, by Country (2021)

Figure 60: South America Wafer-level Test and Burn-in (WLTBI) Market Value Share Analysis, by Country (2031)

Figure 61: South America Wafer-level Test and Burn-in (WLTBI) Market Attractiveness Analysis, By Type

Figure 62: South America Wafer-level Test and Burn-in (WLTBI) Market Attractiveness Analysis, By Applications

Figure 63: South America Wafer-level Test and Burn-in (WLTBI) Market Attractiveness Analysis, by Country

TMRGL82208
May 2021
177 Pages
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