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Still the same website as 2 years ago…
https://thenftmarketplace.io/
Nothing changed.
“We know that the first deal was closed with Polariton.
Because they are researchers (a spin-off) from ETH Zürich, they deserved the licensing deal. Despite initially targeting larger Tier 1 companies due to limited manpower, a smaller yet significant deal was secured. This was made possible specifically because these individuals contributed to the development of the technology. Remember the demonstration of the 800g MZM at ETH’s OFC event. This early engagement showcases LWLG’s commitment to those who have played a crucial role in its advancement.”
https://www.polariton.ch/wp-content/uploads/2022/12/Lightwave-Logic-and-Polariton-Technologies-Announce-World-Class-Figure-of-Merit-for-Plasmonic-Polymer-Optical-Modulators.pdf
A new era in semiconductor design!
Integrating an on-chip modulator, particularly one based on advanced technologies like plasmonic Mach-Zehnder modulators with electro-optic polymers, offers significant advantages for companies involved in chip development. Here's a brainstorm on the potential benefits and the companies that could be most interested:
Enhanced Data Transmission Speeds
Immediate Benefit: The primary advantage of an on-chip modulator is the dramatic increase in data transmission speeds within the chip and between chips in a system. This is critical for high-performance computing tasks, AI, machine learning, and big data analytics, where processing large datasets quickly is key.
Interested Companies: NVIDIA, AMD, Intel, and other companies designing processors for AI, gaming, data centers, and high-performance computing would see immediate benefits from such technology.
Reduced Latency
Communication Efficiency: On-chip optical interconnects can significantly reduce the latency associated with electronic interconnects, improving the overall efficiency of chip communication.
Interested Companies: Companies like Qualcomm and Broadcom, which develop chips for telecommunications and networking equipment, would greatly benefit from the reduced latency for faster signal processing.
Lower Power Consumption
Energy Efficiency: Optical interconnects can be more energy-efficient than their electrical counterparts, especially over longer distances. Integrating modulators directly onto the chip could reduce the overall power consumption of computing systems.
Interested Companies: Mobile and portable device manufacturers like Apple, Samsung, and Huawei could leverage this for longer battery life and lower heat production in devices.
Increased Bandwidth
Handling More Data: The use of optical interconnects allows for higher bandwidth, enabling chips to handle more data simultaneously. This is particularly advantageous for server chips in data centers and for complex calculations in scientific computing.
Interested Companies: Cloud computing giants like Amazon (AWS), Google Cloud, and Microsoft Azure, who are continuously expanding their data center capabilities, would find this technology invaluable.
Scalability and Integration
Flexible System Design: With the miniaturization offered by plasmonic modulators, chips can be designed with more flexibility, allowing for scalable and dense integration of optical interconnects.
Interested Companies: Startups and established firms in the semiconductor industry focusing on next-generation chip designs, like ASML and TSMC, could innovate in manufacturing processes to incorporate these modulators.
Competitive Advantage
Unique Selling Proposition: Having a chip with an integrated on-chip modulator could serve as a strong unique selling proposition, differentiating a company’s products in the market through superior performance metrics.
Interested Companies: Virtually "all semiconductor companies", but especially those in highly competitive markets like consumer electronics, automotive (for autonomous vehicles), and IoT devices, could use this as a differentiator.
In conclusion, the integration of on-chip modulators based on advanced plasmonic and electro-optic technologies could herald "a new era in semiconductor design", offering substantial benefits across various domains. This would not only push the boundaries of what's possible in terms of performance but also open up new product categories and market opportunities for innovative companies.
Today: Paper to be presented at OFC 2024: Presentation ID: W4H.5 Paper Title: Single Carrier net 400 Gbit/s IM/DD over 400 m Fiber Enabled by Plasmonic Mach-Zehnder Modulator
The Plasmonic Mach-Zehnder Modulator employing LWLG's EO polymers emerges as a particularly compelling choice for integration within a hybrid SiPh (Silicon Photonics) platform, as suggested by Google. The fusion of plasmonic technologies with advanced EO polymers opens a powerful avenue for achieving high data speeds and efficiency, crucial for the future evolution of optical communication systems. This approach holds particular promise for applications demanding the utmost in speed and efficiency, such as in data centers and high-performance computing applications.
"Additional On-Chip Capabilities":
Moreover, the unique combination of plasmonic effects and EO polymers provides additional opportunities beyond traditional communication systems, particularly in the realm of "on-chip" optical interconnects. The ability of plasmonic devices to confine light to sub-wavelength dimensions offers a path toward ultra-compact, high-speed modulators that could be integrated directly "onto silicon chips". This could revolutionize chip design by facilitating direct, high-speed optical communication between different parts of a chip or between different chips within a system, potentially bypassing some of the limitations of electronic interconnects.
This miniaturization and integration capability could lead to significant advancements in chip performance, reducing latency and increasing bandwidth within computing systems. On-chip optical interconnects enables more efficient data transfer between processors, memory units, and other components, which is crucial for the development of next-generation computing architectures, including those needed for artificial intelligence and machine learning applications.
The application of LWLG's EO polymers within plasmonic Mach-Zehnder modulators not only aligns with the immediate goals of enhancing data transmission rates and efficiency for telecommunications and data centers but also extends the horizon of silicon photonics into the realm of "on-chip" optical interconnects. This broader application spectrum underscores the transformative potential of combining plasmonic effects with advanced electro-optic materials, setting a foundation for future innovations in both telecommunications and computing technologies.
1. Different Points in the Optical Communication Chain: Marvell’s technology, as described, focuses on the digital signal processing aspect of optical communication, particularly using PAM4 modulation to enhance data throughput in optical networks. This technology is crucial for ensuring signal integrity and maximizing bandwidth in complex, high-speed optical networks, especially as demands for data center bandwidth grow.
2. Plasmonic Mach-Zehnder Modulators’ Role: On the other hand, plasmonic Mach-Zehnder modulators are more about manipulating light at a very fundamental level, using the interaction between light and electrons on metal surfaces (plasmons) to achieve modulation. This technology is critical for the initial phase of converting electronic signals into modulated optical signals, which can then be transmitted over optical fibers.
3. Complementarity of Technologies: Given these differing roles—Marvell’s DSPs enhancing signal processing and transmission over optical networks, and plasmonic modulators focusing on the efficient, high-speed modulation of light at the source—it’s clear that these technologies can complement each other in the broader ecosystem of optical communication. One does not replace the other; instead, they could work together in a system where high-efficiency, high-speed light modulation is needed at the source, and high-quality, high-bandwidth signal transmission is needed in the network.
Therefore, while both technologies aim to improve the efficiency and performance of optical communication systems, their applications are somewhat different but complementary, contributing to different stages of the optical transmission process.
Both technologies are used in data centers and communication networks and both contribute to improving the performance and capacity of optical communication systems, they serve slightly different purposes within the optical communication ecosystem. Marvell's technology can be considered complementary rather than directly competitive with plasmonic Mach-Zehnder modulators, as it enhances the quality and effectiveness of signal transmission at the network level, while plasmonic modulators focus on the fundamental light modulation mechanisms necessary for "data transmission".
From the sec filing yesterday 8k
Dr. Michael Lebby commented: "Our newly presented results are incredibly exciting, representing not only the best commercial-grade-compatible polymer modulators to-date, but on commercial 200mm silicon wafers, with performances that fit very well for a 4-channel x 200Gbps (or 800Gbps) pluggable transceiver, as well as the next generation 4-channel x 400Gbps (or 1600Gbps) pluggable transceivers. 200G lanes with clean, open eye diagrams now represent an inflection-point to extend silicon photonics benefits by utilizing the company's polymers to enable much higher data-rate speeds at significantly lower power consumption levels. These results will position LWLG to support the burgeoning demand of generative AI as datacenters around the world begin to upgrade their hardware faster than expected to meet the demands of the future."
The tier1 will be Google!
See page 23 in the footnote
Demonstration of the mach-zenhder modulator!
Fireworks! the pieces are falling into place.
https://api.mziq.com/mzfilemanager/v2/d/307dbc8b-e212-48ba-9968-8cef3f6b5188/1bd96423-05f6-76f0-82d8-2a80d7a40691?origin=2
The product is ready!
This is the google slide!
https://www.linkedin.com/posts/advanced-photonics-coalition_fiberoptics-technology-innovation-activity-7178065757874913281-L2Oo?utm_source=share&utm_medium=member_ios
Modulators with low driving voltage, high bandwidth, and low loss.
They are also showing the same wafer
And “organic Material” the same picture on page 15 from LWLG
https://api.mziq.com/mzfilemanager/v2/d/307dbc8b-e212-48ba-9968-8cef3f6b5188/1bd96423-05f6-76f0-82d8-2a80d7a40691?origin=2
I can’t believe my eyes!
It is hapening…
This is the google slide!
https://www.linkedin.com/posts/advanced-photonics-coalition_fiberoptics-technology-innovation-activity-7178065757874913281-L2Oo?utm_source=share&utm_medium=member_ios
Modulators with low driving voltage, high bandwidth, and low loss.
They are also showing the same wafer
And “organic Material” the same picture on page 15
I can’t believe my eyes!
It is hapening…
Volume will come after the weekend…
The presentation indicates that Lightwave Logic Inc. has not only developed working products but is also ready to demonstrate them at the Optical Fiber Communication Conference and Exhibition (OFC) 2024. This is confirmed by their mention of a paper presentation on the use of Perkinamine® LWLG polymers for 400Gbps lanes in plasmonic slot devices during the conference. This strongly suggests that they have a functioning prototype or even a production-ready version of their technology, which they plan to present or demonstrate at OFC 2024.
Details about their preparations for a demonstration of packaged polymer slot modulators that support up to 100GBaud PAM4 (200Gbps) further reinforce the assumption that they have a working product. They describe how these modulators require low driving voltages (<2V), indicating advanced technological development and optimization for practical applications.
Moreover, the mention of a commercial material supply license agreement in the second quarter of 2023 and its market acceptance indicates that they have already made steps towards commercialization and possibly already have working products in the hands of customers or partners.
In summary, the information in the presentation strongly suggests that Lightwave Logic has working products and plans to demonstrate this technology at OFC 2024, highlighting their confidence in the applicability and effectiveness of their electro-optic polymers.
Thnx Sam, best news to start the week!
NFTM go!
Source: The wall street journal (24/03/2024)
Bill Vass, vice president of engineering at Amazon Web Services, said the world adds a new data center every three days. Microsoft co-founder Bill Gates told the conference that electricity is the key input for deciding whether a data center will be profitable and that the amount of power AI will consume is staggering.
The surge in AI-driven power demand comes as other factors converge to create new strain on the grid. A wave of manufacturing plants are being developed across the U.S., spurred by new tax policies under the Inflation Reduction Act, and many states are working to use more electric power for transportation, heat and heavy industry.
New data centers can be built faster than new power generation and there is already a supply crunch. Construction timelines for data centers have been extended by two to six years because of power-supply delays, according to commercial-real-estate services firm CBRE Group.
About a third of the world’s 8,000 data centers are in the U.S., but the build-out is a worldwide phenomenon. Globally, the International Energy Agency estimates that electricity consumption from data centers, AI and cryptocurrency could double by 2026.
A data center build-out is also under way in Japan and will test that country’s power resources, said Yukio Kani, CEO of JERA, Japan’s largest power provider.
That’s what I’ saying
Step 1: Reverse Split (100:1)
• Before the reverse split, the company had 165,608,379 common shares issued and outstanding.
• After the reverse split (at a ratio of 100:1), for every 100 existing common shares, they are combined into 1 new common share. This results in a reduced number of common shares to 1,656,084.
Step 2: Conversion of Preferred Shares
• The company had 26 shares of preferred stock, each convertible into 10,000,000 common shares.
• After conversion of the 26 preferred shares, an additional 260,000,000 common shares are issued, bringing the total to 261,656,084 common shares.
Conclusion
After these two steps, the total number of common shares increases from 1,656,084 (post-reverse split) to 261,656,084 (after the conversion of preferred shares).
Dilution Calculation
To calculate the dilution of the original common shares compared to the total shares after both steps:
• Original Common Shares After Reverse Split: 1,656,084
• Total Common Shares After Conversion of Preferred Shares: 261,656,084
• Dilution = (Original Common Shares / Total Common Shares) * 100 to get the percentage of the original shares in the new total.
The dilution of the original common shares, compared to the total shares after both the reverse split and the conversion of preferred shares, is approximately 0.63%. This means the original common shares constitute about 0.63% of the total common shares after these transactions.
Where did you read this?
“What I didn't expect was for Ben Quick to convert his shares to common and put himslef in the same boat as us.
Because I don’t think so…. The 26 preferred shares will still exist.
Ok 100 to 1 then
But 1 preferred share of 26 can be transferred in to 10.000.000 shares.
So we will own a total of 10mil. and they will own 260 mil.
Do the math…
Hell yes!
It takes years to develop waffers…
They are ready!
Wrong
10 to 1
So 500.000.000 to 50.000.000
And then they change the 26 preferred shares into 260.000.000
50.000.000 + 260.000.000 = 310.000.000
They need 50.000.000 for trading, float rotation.
If they do 100 to 1 the kill the stock!
If they pull off Finra…
Nope 10 to 1
Gentlemen, it's finally happening. After a long time, I've consulted Sunbiz Florida again and what turns out... the name change is finally a fact! See link.
https://search.sunbiz.org/Inquiry/CorporationSearch/ConvertTiffToPDF?storagePath=COR%5C2024%5C0301%5C24692265.Tif&documentNumber=P05000053335
It indeed seems strategically planned. Announcing the annual shareholder meeting shortly before a significant conference could be a way to generate interest and attention. By hinting at a product demonstration during the meeting, they could be building anticipation for what might be shown at the conference. This could serve as a signal to both shareholders and the broader market that there are significant developments or innovations on the horizon. It could indeed be seen as a tactic to say, "We have something exciting in the pipeline, stay tuned for more details." This approach can help to keep attention focused and possibly enhance the company's value perception in the lead-up to the conference.
It’s a business…
So they’re trying to launch a nft website too. But for now they’re unsuccesfull due to Finra.
Maybe they succeed, maybe not.
We will see, soon enough. The story with finra can’t last forever.
Although the announced advancements in computational lithography by NVIDIA, TSMC, and Synopsys are not directly related to LWLG’s technology, they highlight the ongoing innovation within the semiconductor industry. LWLG’s focus on improving optical data transmission complements the objectives of chip fabrication improvements. The increasing complexity and performance requirements of modern chips may lead to a heightened demand for advanced data transmission technologies, presenting opportunities for companies like Lightwave Logic.
National Reconnaissance Office (NRO): The NRO is responsible for designing, building, launching, and maintaining America’s reconnaissance satellites. It plays a critical role in national security and global intelligence operations.
• Properties Branch of the Army Research Laboratory on the Aberdeen Proving Grounds in Aberdeen, Maryland: While the exact designation “Properties Branch” might vary, the Army Research Laboratory (ARL) is part of the Aberdeen Proving Ground (APG) in Maryland. APG is a significant testing and research center for the U.S. Army, focusing on various technological and material developments and validations.
• Defense Advanced Research Projects Agency (DARPA): DARPA is an agency of the United States Department of Defense responsible for the development of emerging technologies for military use. DARPA has a long history of supporting groundbreaking technological advancements.
• Naval Air Warfare Center Weapons Division in China Lake, California: This is a branch of the U.S. Navy that focuses on the research, development, testing, and evaluation of air-based weapon systems. Located in China Lake, California, it plays a vital role in the development of weapons for the U.S. Navy and Marine Corps.
• Air Force Research Laboratory at Wright-Patterson Air Force Base in Dayton, Ohio: This laboratory is a scientific research organization for the United States Air Force, dedicated to developing advanced warfare technologies. Located at Wright-Patterson Air Force Base in Ohio, it conducts a wide range of research activities across various technological fields.
Each of these institutions uniquely contributes to the research and development efforts of the U.S. defense.
Go LWLG!
The patent from Lightwave Logic Inc. provides a potentially significant solution for the protection and ubiquity of electro-optic (EO) polymers. It specifies the integration of nonlinear optical (NLO) chromophores with one or more attached diamondoid groups into EO polymers, ensuring a high degree of macroscopic nonlinearity and sufficient thermal, chemical, and photochemical stability. These properties are crucial for commercially viable devices.
The NLO chromophores with diamondoid groups exhibit increased poling efficiency and increased loading when dispersed within a host polymer matrix. This could lead to enhanced electro-optic activity in EO polymers by increasing the concentration of NLO chromophores within a host polymer and enhancing the electro-optic properties of the chromophores. However, some techniques for increasing the chromophore concentration may reduce temporal stability.
The concurrent resolution of these dual issues – increasing the NLO chromophore concentration while maintaining temporal stability – is seen as the final barrier in the widespread commercialization of EO polymers in numerous devices and systems. This suggests that the patent from Lightwave Logic could represent a significant breakthrough in overcoming this barrier, potentially making EO polymers more ubiquitous across a range of applications.
The specific feature of the patent pertains to the long-term thermal stability of the developed nonlinear optical (NLO) chromophores attached with one or more diamondoid groups. These chromophores exhibit significant thermal stability over extended periods, which is significant for their usability in electro-optic devices. In the document, this is illustrated by the stability of the electro-optic coefficient (r33) of thin films that have been stored over time at 85°C. The results demonstrate that the electro-optic performance of thin films using a chromophore according to an embodiment of the present invention exhibit significant long-term thermal stability.
This is important for the scalable volume production and reliability of electro-optic devices, as it provides the ability to produce stable materials suitable for commercial applications where long-term performance under heat is a crucial factor.
The patent describes applications of the invented nonlinear optical materials for various electro-optic devices and systems. This includes:
Phased array radar
Satellite and fiber telecommunications
Cable television (CATV)
Optical gyroscopes for application in aerial and missile guidance
Electronic countermeasure (ECM) systems
Backplane interconnects for high-speed computation
Ultrafast analog-to-digital conversion
Landmine detection
Radio frequency photonics
Spatial light modulation
All-optical (light-switching-light) signal processing
Additionally, the patent indicates that because of the very broad absorption spectrum of the nonlinear optical chromophores, which cover the entire UV-visible-near infrared region from 250 nm to 1800 nm at a high extinction coefficient, the nonlinear optical materials can also be used for solar energy conversion and photovoltaic devices.
It’s only 400million because LWLG has 100 million in the bank.
I’m only allowed to sell. I’m on IBKR.
So that means that volume comes in after the ticker change. No green light from Finra, no volume.
I’m sure that only a few brokers allow you to buy the stock.
After the ticker change bid and ask will move closer together.
Finra … jezus.
Lets burn them all!
It is time… the stockmarket is like early post corona again. Huge volumes and burning short positions like supernova’s.
News has to drop soon and were off to races.
We’re going to burn your short position. Be ready to cry…
Volume rising!
I lite it.
If we close above 0,019 we have a technical break-out on the daily chart. (Falling wedge since 2022/13/10)
Good days coming…
12/30/2023
Q4 2023 UPDATE
Q4 2023 UPDATE Market: Q4 2023 has been a difficult quarter due to regulatory challenges. In Q3, FINRA rejected the company's proposed corporate action due to three missing reporting filings from 2012 and 2013. Unfortunately, following an appeal process, the regulator confirmed these missing filings were in breach of their rules. Q4 saw the company adhere to this request and, from October to December, produce and submit the three historic filings covering 2012 and 2013. Subsequently, a new corporate action application has now been submitted to FINRA, and we now await their feedback. We expect a seamless process due to the time and effort spent addressing all the points, including the three historic filings in the first application from Q1 2023. Once FINRA has responded, a new update will be available. Operations: The company has continued to develop it's marketplace and has been given a Q1 2024 completion date from its developers. The company has continued to grow its social media accounts, mainly through organic growth. Once the platfrom is completed, the social media accounts will be beneficial to attract new users to the marketplace. The company has also enlisted the services of a UK marketing specialist to maximise the growth of new users using an email marketing strategy. A further update will be posted in Q1 2024. Ben Quick CEO The NFT Marketplace LTD
No, Ben bought the shares from Synergy after the Brits sold/gave back BALB to Synergy.
But strange that after the transaction the name changed to Edgemode. it had anything to do with the sunbiz florida.
But strange that the namechange on 04/03/2024 isn’t mentionted…
Let’s hope this doesn’t mess things up in more delay.
I bought my share way back before it was transferred to the Brits. I lost some dollars.
But I’m confident when the get things right, I will get my dollars back and more a lot more!
2024 will be the year!
https://search.sunbiz.org/Inquiry/CorporationSearch/SearchResultDetail?inquirytype=EntityName&directionType=Initial&searchNameOrder=BUILDABLOCK%20P050000533352&aggregateId=domp-p05000053335-1c5fd9f6-cbe1-4f9a-8850-6e0dfdfd3df5&searchTerm=Buildablock&listNameOrder=BUILDABLOCK%20P050000533352
Me too…
—
From The all seeing eye
2023/09/19
Verified profile removed.
What does this mean?
If a company’s “verified profile” has been removed, it might mean that:
1. The company failed to maintain the updated information required for the status.
2. The platform found discrepancies or issues with the provided information.
3. The company chose to withdraw its verified profile for some reason.
If the company has applied to become current again, it suggests they are trying to regain or upgrade their status on the OTC market by adhering to the necessary reporting and compliance requirements. This could involve updating their financial reports, adhering to certain standards, or correcting any discrepancies that led to the removal of their “verified profile” in the first place.
—-
So I think it will be the last step to get everything right and then to Finra again.
Best scenario: Tomorrow the good news
On every investor’s radar over the weekend.
Monday: Strong opening with higher prices!
Tuesday: Continuation of the positive trend!
It will be a banger either way. Up or down!