Solar/PV has been doing the rounds consistently, and has probably now become one of the most hyped sectors.
In fact, renewable energy has never ever had such a good time! As mentioned, a tremendous hype has already been built around solar photovoltaics. Several companies, in India, and elsewhere, have also jumped into the solar bandwagon.
So what are the reasons behind this 'sudden' interest in solar? According to Dr. Ashok Das, managing director, Solar Solutions, and a well know expert in this area, consumers do not yet drive the solar energy sector. Being energy, it is mostly driven by the government and its subsidies.
So, why has there been this 'sudden interest' in solar? There are two reasons.
First, the climate change issue started getting center stage at world forums, leading to policies and targets to cut global warming, and hence boosting renewable energy. Second, the soaring oil prices and continued dependence on a few countries for oil has led to the realization of the energy security.
There are several takeaways from the European experience with solar. Dr. Das says that Europe, particularly, has taken solar very seriously. They have been a leader in solar. "Germany, for instance, gave away all of the necessary subsidies to attain energy security. These subsidies have led to the solar boom. It has also led to an increased R&D to bring down the cost of solar energy."
Nevertheless, he adds there seems to be a bubble forming in this sector, like all other booms in the past. The industry will go through consolidation as the market matures.
And where does India stand in comparison? According to Dr. Das, steps are being taken to promote solar energy in India. "As of now, the feed-in tariff is Rs. 15 for photovoltaics and Rs. 12 for thermal solar. The government also announced a mandatory 5 percent renewable energy mix in the electricity production.
"The PMO (Prime Minister's Office) has also issued a National Action Plan that has plans for boosting solar. These subsidies are driving some of the increased activities in India."
He contends: "We need stronger lobbying so that better subsidies can come through. Therefore, most of the manufacturing activities in India are still driven by the export markets."
Surely, given the surge of investments in solar within India, there is every room for developing a very good ecosystem.
Dr. Das says: "Coming to the solar ecosystem, we already make solar products, as well as the modules. We also have the capability to make cells. The only part missing has been wafer, the silicon for solar.
"A few silicon factories should be coming up in India soon. So, India can easily establish the entire ecosystem for solar photovoltaics."
Postscript: More investments in solar today, in India. According to Hindu Business Line, there have been three additional investments worth Rs. 55,000 crores.
Vavasi Telegence to invest Rs 39,000 crore for solar PV and polysilicon unit; EPV Solar to invest Rs 4,000 crore for solar PV unit; and Lanco Solar to invest Rs 12,938-crore for solar PV and polysilicon unit.
A word of caution: It's advisable not to get carried away by all the success in solar. Solar is/was only part of the ecosystem units in the Indian semicon policy.
Don't forget semiconductors!
While this success in solar does augur well for the solar industry in India, don't think this is even close to what the Indian semicon policy, launched with fanfare last September, originally set out to achieve!
Monday, September 22, 2008
Friday, September 12, 2008
Synopsys' Dr Chi-Foon Chan on India, low power design and solar
There have been reports about the troubles within the EDA industry in recent times, especially those related with quarter sales. Interestingly, Synopsys has been the one sailing along fine! If that's not enough, it made its intention known of playing a role on the solar/PV segment, an area where lot of investments have been happening!
Given this scenario, I was fortuitous enough, rather, extremely lucky to be able to get into a conversation with Dr. Chi-Foon Chan, President and Chief Operating Officer, Synopsys Inc., during his recent visit to India.
On the state of the global semiconductor industry, he said, it was somewhere now in the low 10s [well below 10 percent]. The EDA industry is currently tracking below that level. However, Synopsys has been growing at around 10 percent. He said, "The technology challenges today are very high."
Synopsys has a substantial number of R&D population based out of India. Giving his assessment of the Indian semiconductor industry, Dr. Chan added: "Our main interest in India is largely talent and the academia. India can very well get more into the product development side. Even the outsourcing of designs have increased. Our capabilities, of the Indian team, have also increased."
As with any good semiconductor ecosystem, the Indian industry also needs a proactive industry association, a role played to near perfection by the ISA (India Semiconductor Association). Acknowledging the ISA's role, Dr. Chan said, "The ISA has also formed a very cohesive team."
There is little doubt about India's growing importance in technology strengths and managerial leadership. Dr. Chan added: "We are more on the high-end side and also track what others design. In India, the profiles of designs are definitely high-end in nature. This is largely due to the presence of a large number of MNCs. A very high percentage of designs are in the 45nm and 65nm process technology nodes."
There is another significant indicator of India's growing importance, and that is the huge rise in the attendance of the SNUG. In 2000, this event attracted 180 people. However, in 2008, the SNUG attracted over 2,000 people.
Moving India to next level
Given the very high level of commitment on Synopsys' part toward India, there was a need to find out from Dr. Chan what exactly India needs to do to move to the next level in the value chain in the semiconductor ecosystem.
He advised: "India can do two to three things. One, for the system to grow, you need the government, academia and industry to grow together. India has all of the ingredients required to drive products."
Comparing India with China, he highlighted the fact that while in China, the local consumption was higher than local supply, that was not the case with India!
"Therefore, looking at merely the local market is not the only thing. Products developed here can also be targeted at the Middle East and Southeast Asia." He was quite forthright in his analysis, adding: "Industries start when you find markets. The skill sets are already present here. There can well be multiple startups."
Dr. Chan also touched upon the fab vs. fabless issue, noting that there could well be more of fabless companies in India. "Building a fab requires lot of capital. Also, consolidation will continue to happen."
What role does Dr. Chan see Synopsys playing in the Indian context? He said: "Synopsys will continue to be a catalyst for the industry. A healthy design industry in India continues to help us. We also work well with the Indian universities. Having more people from the universities will always help. We also invest a lot in application support. The application team also trains others. I now look forward to seeing more fabless companies here and India to become even more global."
On low power design
India is also a centre of expertise in low power design, given that low power is hugely important in today's electronics ecosystem. Dr. Chan commented that low power has always been the number one design issue. It cannot be taken care of at one single stage.
He added: "A slightly new concept that has emerged is low-power verification. There are so many schemes for attacking low power, such as multiple voltage islands. We (Synopsys) are spending a lot of effort in low power.
"As a designer, you require detailed analysis. Low-power verification is now coming up. Another area is testing. As an example, if so much power is required, how do you have the power cut from the tool you are using to test? From a Synopsys point of view, we are involved in several points, such as front-end synthesis, testing, sign-off, verification, etc. We are trying to put in a whole lot of methodologies."
Synopsys in solar
EDA may be able to help by lowering power requirements and leakage on better products. Especially, the Synopsys' TCAD product can be used to create more efficient and effective solar cells. Now, this is not a new development anymore. Synopsys, along with Magma, have already made known their intentions about setting foot in the solar/PV space.
On the TCAD, Dr. Chan said: "We have a very strong position in the TCAD, commercially. Now, it is one of our most critical elements in high-performance. Our TCAD is among the strongest in the EDA industry.
"In solar, it does not have to be a complicated place-and-route, etc. From an entire solar industry point of view, we have now used some effort from TCAD into this space. Heat transfer issues, etc., are more in the EDA space."
I will continue my conversation with Synopsys on its solar initiative sometime later. Keep watching this space, folks
Given this scenario, I was fortuitous enough, rather, extremely lucky to be able to get into a conversation with Dr. Chi-Foon Chan, President and Chief Operating Officer, Synopsys Inc., during his recent visit to India.
On the state of the global semiconductor industry, he said, it was somewhere now in the low 10s [well below 10 percent]. The EDA industry is currently tracking below that level. However, Synopsys has been growing at around 10 percent. He said, "The technology challenges today are very high."
Synopsys has a substantial number of R&D population based out of India. Giving his assessment of the Indian semiconductor industry, Dr. Chan added: "Our main interest in India is largely talent and the academia. India can very well get more into the product development side. Even the outsourcing of designs have increased. Our capabilities, of the Indian team, have also increased."
As with any good semiconductor ecosystem, the Indian industry also needs a proactive industry association, a role played to near perfection by the ISA (India Semiconductor Association). Acknowledging the ISA's role, Dr. Chan said, "The ISA has also formed a very cohesive team."
There is little doubt about India's growing importance in technology strengths and managerial leadership. Dr. Chan added: "We are more on the high-end side and also track what others design. In India, the profiles of designs are definitely high-end in nature. This is largely due to the presence of a large number of MNCs. A very high percentage of designs are in the 45nm and 65nm process technology nodes."
There is another significant indicator of India's growing importance, and that is the huge rise in the attendance of the SNUG. In 2000, this event attracted 180 people. However, in 2008, the SNUG attracted over 2,000 people.
Moving India to next level
Given the very high level of commitment on Synopsys' part toward India, there was a need to find out from Dr. Chan what exactly India needs to do to move to the next level in the value chain in the semiconductor ecosystem.
He advised: "India can do two to three things. One, for the system to grow, you need the government, academia and industry to grow together. India has all of the ingredients required to drive products."
Comparing India with China, he highlighted the fact that while in China, the local consumption was higher than local supply, that was not the case with India!
"Therefore, looking at merely the local market is not the only thing. Products developed here can also be targeted at the Middle East and Southeast Asia." He was quite forthright in his analysis, adding: "Industries start when you find markets. The skill sets are already present here. There can well be multiple startups."
Dr. Chan also touched upon the fab vs. fabless issue, noting that there could well be more of fabless companies in India. "Building a fab requires lot of capital. Also, consolidation will continue to happen."
What role does Dr. Chan see Synopsys playing in the Indian context? He said: "Synopsys will continue to be a catalyst for the industry. A healthy design industry in India continues to help us. We also work well with the Indian universities. Having more people from the universities will always help. We also invest a lot in application support. The application team also trains others. I now look forward to seeing more fabless companies here and India to become even more global."
On low power design
India is also a centre of expertise in low power design, given that low power is hugely important in today's electronics ecosystem. Dr. Chan commented that low power has always been the number one design issue. It cannot be taken care of at one single stage.
He added: "A slightly new concept that has emerged is low-power verification. There are so many schemes for attacking low power, such as multiple voltage islands. We (Synopsys) are spending a lot of effort in low power.
"As a designer, you require detailed analysis. Low-power verification is now coming up. Another area is testing. As an example, if so much power is required, how do you have the power cut from the tool you are using to test? From a Synopsys point of view, we are involved in several points, such as front-end synthesis, testing, sign-off, verification, etc. We are trying to put in a whole lot of methodologies."
Synopsys in solar
EDA may be able to help by lowering power requirements and leakage on better products. Especially, the Synopsys' TCAD product can be used to create more efficient and effective solar cells. Now, this is not a new development anymore. Synopsys, along with Magma, have already made known their intentions about setting foot in the solar/PV space.
On the TCAD, Dr. Chan said: "We have a very strong position in the TCAD, commercially. Now, it is one of our most critical elements in high-performance. Our TCAD is among the strongest in the EDA industry.
"In solar, it does not have to be a complicated place-and-route, etc. From an entire solar industry point of view, we have now used some effort from TCAD into this space. Heat transfer issues, etc., are more in the EDA space."
I will continue my conversation with Synopsys on its solar initiative sometime later. Keep watching this space, folks
Labels:
Dr. Chi Foon-Chan,
EDA,
EDA Tools,
fabless,
fabs,
global solar industry,
India semiconductor market,
ISA,
low power design,
Magma,
PV,
Semiconductors,
Solar,
solar/PV,
Synopsys,
TCAD
Thursday, September 11, 2008
Magma's YieldManager could make solar 'rock'!
Make no mistake, folks! The EDA guys are getting their act together to penetrate the solar/PV segment!! Magma's YieldManager is a great example of that effort! Yes, we all know the troubles of the EDA industry as well as of the key players. However, let's not ignore this initiative from Magma!
Recently, Magma Design Automation Inc. announced the development of a new yield enhancement software system, the YieldManager software system, which is customized for solar fabs to improve conversion efficiency, increase yield and reduce the manufacturing costs of solar cells.
Magma is collaborating with Pegasus Semiconductor-Solar to refine the product specifications and test the new product, based on Magma's YieldManager.
This is an interesting development, especially from the point of view of the solar/PV industry! Even more significant is the entrance of the EDA community [the one being Synopsys] into solar/PV, a segment, which has witnessed a substantial amount of investments worldwide, and specifically, in India.
It was fun catching up with Ankush Oberai, VP, Failure Analysis Business Unit, Magma Design Automation, in Silicon Valley, to find out more about the YieldManager software system, what it can do for the solar/PV industry, and why Magma decided to venture into an 'unchartered territory'.
The first and most obvious thing, why YieldManager?
Ankush Oberoi says that in semiconductors, yield impacting parameters which are regularly monitored are mostly extrinsic, i.e., from outside, such as particles, over-exposure, under-exposure and miss-processing. In solar cells, the yield impacting parameters are mostly intrinsic, that is, something built into the solar cell material which can NOT be easily seen. Thus, a different "eye" is needed to see the solar parameters. The "eye" is the YieldManager here!!!
It would NOT be either inspection tools or litho optical proximity correction (OPC) detector. The solar cell efficiency is directly influenced by electro-physics of solar materials. A YieldManger is required to monitor any changes in those efficiency impacting parameters.
The most important parameter is the lifetime of current-generating carriers. As the solar energy generates the "hole-electron" pairs, they are collected separately as electricity.
If the solar material is "dirty" with many crystalline boundaries as in thin film solar cells, the solar generated hole-electrons get pulled into those crystalline boundaries and do not contribute to the electricity generation.
"Thus, if we can find a solar yield management system to detect the very subtle change in carrier lifetime, then we are at home with a greatest Home Run in solar cell business," he contends.
Given the EDA background, why did Magma decide on a yield management technology?
He adds that yield management technology was acquired by Magma as part of the Knights Technology acquisition in Nov 2006. Magma's Fab Business Unit (formerly, Knights Technology) is a pioneer (since 1994) in yield management for semiconductor technology.
The product is deployed and used in leading fabs around the world to help manage production wafer yield. Yield management has also been deployed for mask making and LCD productions.
It would be interesting to know how Magma's new product will allow solar fabs to better monitor all metrology, inspection and performance data throughout the manufacturing process.
Oberoi says: "For Si wafer solar cell, the most important parameter to monitor is the solar conversion efficiency impacting parameters. An example would be a carrier lifetime.
"If the carrier lifetime fluctuates more than normal, the solar Yield Manager will quickly examine all of the key data, i.e., metrology, inspection and performance data, to pinpoint out potential root-causes of the fluctuation problem."
For thin film solar cell, particles, laser cutting integrity and film thickness uniformity would be main things to monitor. Those data are quite similarly collected, as in semiconductors, and would be monitored as similar ways. The Solar Yield Manager would do well as proven in semiconductors in this case.
Next, it is important to find out how will the YieldManager enable fab operators to identify and correct root causes of solar-efficiency and yield degradation caused by subtle fab processing fluctuations or instability.
According to Oberoi, the carrier lifetime, which could be caused by various factors, is the most critical parameter to monitor for achieving and maintaining the good solar conversion efficiency.
He says: "As the Solar Yield Manager carefully monitors those factors, blindly committing ~400,000 wafers a day can be eliminated, when critical process instability starts appearing and persists. The solar conversion efficiency impacting factors could be monitored differently by different solar fabs."
Some fabs may not have capabilities to monitor those factors. The Solar Yield Manager would define those metrology and performance tool requirements, when released.
It is also interesting to learn how improving the energy conversion efficiency, reducing the manufacturing costs and increasing the yield of silicon wafer-based solar cells are critical to the growth of the solar market.
Currently, the Si wafer for solar cell costs $2~$2.5/watt due to the severe shortage of Si. The selling price of a solar cell is $3~$3.5/watt, that is, the material cost is 60~70 percent of the solar cell price.
No market or industry would prevail with the 60~70 percent material cost, adds Oberoi. Thus, every milli-watt squeezed out of a solar cell would be very critically important for proliferation of solar industry.
In order to increase the power output of a solar cell, the solar conversion efficiency must be maximized. Once maximized, sustaining the good solar efficiency is the name of the game in the solar cell manufacturing business.
The effective manufacturing cost will be drastically lowered, if bad solar cells with poor solar efficiency is minimally produced. That is, some fabs will use ~400,000 wafers a day to generate ~500 M-Watt a year, whereas some ~450,000 wafers to do the same with poorer solar efficiency.
Innovation in the solar fabrication process must be accelerated, and today, no other enterprise-wide yield enhancement software exists for solar fabs.
Oberoi says: "Solar cell is an old technology, but a very new industry, simply because not enough money was being invested. Now, money is pouring into the solar industry and products like solar Yield will start to appear. It is not known yet that anyone commercially has tried to develop a similar product."
Global estimate of solar/PV industry
There are several publications with recent estimates. The annual solar cell installation in the world: Germany ~46 percent, Japan ~23 percent, USA ~9 percent, Spain ~6 percent, Italy ~4 percent, the rest of Europe ~1 percent, the rest of Asia, including India and China ~6 percent, and the rest of world ~5 percent in 2006.
Magma is currently in the design and implementation stages of the product and plan to have version 1.0 of the product commercially available in Q1-09. The company has targeted solar fabs based in Asia that are eager for early implementation of the solar yield product.
Right then: those planning or having solar fabs! Now's the time to test that home run theory with the YieldManager.
Recently, Magma Design Automation Inc. announced the development of a new yield enhancement software system, the YieldManager software system, which is customized for solar fabs to improve conversion efficiency, increase yield and reduce the manufacturing costs of solar cells.
Magma is collaborating with Pegasus Semiconductor-Solar to refine the product specifications and test the new product, based on Magma's YieldManager.
This is an interesting development, especially from the point of view of the solar/PV industry! Even more significant is the entrance of the EDA community [the one being Synopsys] into solar/PV, a segment, which has witnessed a substantial amount of investments worldwide, and specifically, in India.
It was fun catching up with Ankush Oberai, VP, Failure Analysis Business Unit, Magma Design Automation, in Silicon Valley, to find out more about the YieldManager software system, what it can do for the solar/PV industry, and why Magma decided to venture into an 'unchartered territory'.
The first and most obvious thing, why YieldManager?
Ankush Oberoi says that in semiconductors, yield impacting parameters which are regularly monitored are mostly extrinsic, i.e., from outside, such as particles, over-exposure, under-exposure and miss-processing. In solar cells, the yield impacting parameters are mostly intrinsic, that is, something built into the solar cell material which can NOT be easily seen. Thus, a different "eye" is needed to see the solar parameters. The "eye" is the YieldManager here!!!
It would NOT be either inspection tools or litho optical proximity correction (OPC) detector. The solar cell efficiency is directly influenced by electro-physics of solar materials. A YieldManger is required to monitor any changes in those efficiency impacting parameters.
The most important parameter is the lifetime of current-generating carriers. As the solar energy generates the "hole-electron" pairs, they are collected separately as electricity.
If the solar material is "dirty" with many crystalline boundaries as in thin film solar cells, the solar generated hole-electrons get pulled into those crystalline boundaries and do not contribute to the electricity generation.
"Thus, if we can find a solar yield management system to detect the very subtle change in carrier lifetime, then we are at home with a greatest Home Run in solar cell business," he contends.
Given the EDA background, why did Magma decide on a yield management technology?
He adds that yield management technology was acquired by Magma as part of the Knights Technology acquisition in Nov 2006. Magma's Fab Business Unit (formerly, Knights Technology) is a pioneer (since 1994) in yield management for semiconductor technology.
The product is deployed and used in leading fabs around the world to help manage production wafer yield. Yield management has also been deployed for mask making and LCD productions.
It would be interesting to know how Magma's new product will allow solar fabs to better monitor all metrology, inspection and performance data throughout the manufacturing process.
Oberoi says: "For Si wafer solar cell, the most important parameter to monitor is the solar conversion efficiency impacting parameters. An example would be a carrier lifetime.
"If the carrier lifetime fluctuates more than normal, the solar Yield Manager will quickly examine all of the key data, i.e., metrology, inspection and performance data, to pinpoint out potential root-causes of the fluctuation problem."
For thin film solar cell, particles, laser cutting integrity and film thickness uniformity would be main things to monitor. Those data are quite similarly collected, as in semiconductors, and would be monitored as similar ways. The Solar Yield Manager would do well as proven in semiconductors in this case.
Next, it is important to find out how will the YieldManager enable fab operators to identify and correct root causes of solar-efficiency and yield degradation caused by subtle fab processing fluctuations or instability.
According to Oberoi, the carrier lifetime, which could be caused by various factors, is the most critical parameter to monitor for achieving and maintaining the good solar conversion efficiency.
He says: "As the Solar Yield Manager carefully monitors those factors, blindly committing ~400,000 wafers a day can be eliminated, when critical process instability starts appearing and persists. The solar conversion efficiency impacting factors could be monitored differently by different solar fabs."
Some fabs may not have capabilities to monitor those factors. The Solar Yield Manager would define those metrology and performance tool requirements, when released.
It is also interesting to learn how improving the energy conversion efficiency, reducing the manufacturing costs and increasing the yield of silicon wafer-based solar cells are critical to the growth of the solar market.
Currently, the Si wafer for solar cell costs $2~$2.5/watt due to the severe shortage of Si. The selling price of a solar cell is $3~$3.5/watt, that is, the material cost is 60~70 percent of the solar cell price.
No market or industry would prevail with the 60~70 percent material cost, adds Oberoi. Thus, every milli-watt squeezed out of a solar cell would be very critically important for proliferation of solar industry.
In order to increase the power output of a solar cell, the solar conversion efficiency must be maximized. Once maximized, sustaining the good solar efficiency is the name of the game in the solar cell manufacturing business.
The effective manufacturing cost will be drastically lowered, if bad solar cells with poor solar efficiency is minimally produced. That is, some fabs will use ~400,000 wafers a day to generate ~500 M-Watt a year, whereas some ~450,000 wafers to do the same with poorer solar efficiency.
Innovation in the solar fabrication process must be accelerated, and today, no other enterprise-wide yield enhancement software exists for solar fabs.
Oberoi says: "Solar cell is an old technology, but a very new industry, simply because not enough money was being invested. Now, money is pouring into the solar industry and products like solar Yield will start to appear. It is not known yet that anyone commercially has tried to develop a similar product."
Global estimate of solar/PV industry
There are several publications with recent estimates. The annual solar cell installation in the world: Germany ~46 percent, Japan ~23 percent, USA ~9 percent, Spain ~6 percent, Italy ~4 percent, the rest of Europe ~1 percent, the rest of Asia, including India and China ~6 percent, and the rest of world ~5 percent in 2006.
Magma is currently in the design and implementation stages of the product and plan to have version 1.0 of the product commercially available in Q1-09. The company has targeted solar fabs based in Asia that are eager for early implementation of the solar yield product.
Right then: those planning or having solar fabs! Now's the time to test that home run theory with the YieldManager.
Subscribe to:
Posts (Atom)