List of Information Systems products
- classification:Information Systems
3151~3165 item / All 8300 items
Amino acid-derived natural cationic polymer that can be used in food preservatives, hygiene materials, and daily necessities. It is a safe material as it is a fermentation product produced by natural ...
- Shelf life enhancer
Introduction of the preservative polylysine / fermented polyamino acids that contribute to food poisoning prevention.
We provide easy-to-understand materials explaining the natural preservative polylysine, which prevents food poisoning. ε-Polylysine (hereafter referred to as polylysine) is an amino acid-derived preservative widely used as a food preservative. By adding polylysine, the growth of microorganisms that cause food poisoning can be prevented. Every year, food poisoning caused by microorganisms is a significant issue and is frequently reported in the news. Even foods that do not appear to be spoiled can rapidly proliferate microorganisms if the growth environment is suitable, so caution is necessary. Even if something looks clean, contamination by bacteria can progress, posing a risk of food poisoning. By ensuring hygiene management during the manufacturing process, proper storage at appropriate temperatures, and the appropriate use of the preservative polylysine, food safety can be more effectively protected. 【Features】 ■ A safe material produced through fermentation by natural microorganisms (not genetically modified organisms) ■ Provides a good image as a natural fermented product ■ Listed in the existing additive registry as a food preservative ■ A safe domestic product *Please feel free to contact us.
Can be processed into various shapes, with a wide range of application possibilities! We will polymerize the polymer according to your requirements.
- Public Testing/Laboratory
- Contract manufacturing
Equipped with features suitable for FPGA design and verification.
- Other information systems
Free Webinar: In a nutshell, FPGA Design Verification - Part 3
With the evolution of FPGA technology, traditional programmable logic areas have been supplemented by CPUs, GPUs, and high-speed peripherals, making design verification increasingly challenging. Relying solely on physical verification for FPGA testing is clearly insufficient for safety-critical designs, and FPGA teams are adopting advanced design verification methodologies and techniques to develop their own verification processes. In this final installment of the webinar series, we will introduce advanced verification solutions such as scoreboards, checkers, functional coverage, and assertions. We will also cover transaction-based debugging and unit linting features, as well as regression testing using Riviera-PRO.
We will meet the verification needs of engineers creating next-generation FPGAs and SoCs!
- Other information systems
Free Webinar: In a nutshell, FPGA Design Verification - Part 3
With the evolution of FPGA technology, traditional programmable logic areas have been supplemented by CPUs, GPUs, and high-speed peripherals, making design verification increasingly challenging. Relying solely on physical verification for FPGA testing is clearly insufficient for safety-critical designs, and FPGA teams are adopting advanced design verification methodologies and techniques to develop their own verification processes. In this final installment of the webinar series, we will introduce advanced verification solutions such as scoreboards, checkers, functional coverage, and assertions. We will also cover transaction-based debugging and unit linting features, as well as regression testing using Riviera-PRO.