Phase Four’s Post

🌌 Paktron’s MLP Film Capacitors for LEO and SmallSAT Space Missions🌌 Rigorously tested to meet or exceed MIL-STD-202 requirements, Quantic™ Paktron capacitors are designed for the toughest environments, offering a remarkable 25% weight reduction over equivalent MLCCs, which helps minimize satellite weight and launch costs. With an operating range from -55°C to 125°C, they ensure exceptional reliability under the extreme conditions of space. 🌡️ Key Advantages: ⭐ Meets or exceeds MIL-STD-202 standards ⭐ Exceptionally stable performance in varying conditions ⭐ Ultra-low ESR/ESL for optimal circuit performance ⭐ High ripple current capability ⭐NEPP tested When you choose Quantic™ Paktron, you invest in components that stand up to shock, vibration, solderability, and other stringent criteria. Elevate your projects with capacitors you can trust for mission-critical reliability! Learn More https://lnkd.in/eqEK9D9X #SpaceTech #CommercialMissions #CubeSats #SmallSats #LEO #Suborbital #QuanticPaktron #MLPFilmCapacitors #MILSTD202 #DependablePerformance

The current #satellite communications infrastructure is unable to meet the relentless worldwide need for dependable, high-speed broadband access. The existence of this gap is driving the swift creation, advancement and implementation of satellite constellations for low-Earth-orbit (LEO) and medium-Earth-orbit (MEO) communications. These satellites have significantly transformed connection and #data transmission by simplifying worldwide internet access and enabling real-time Earth observation. Nevertheless, in the middle of their capacity for profound change, they face a substantial obstacle: power management. In an interview with Power Electronics News, Matthew Renola, Senior Director for the Vicor Corporation #Aerospace and Defense business unit, discussed the power delivery network challenges this new class of smaller but more powerful satellites pose with their advanced, higher-power network communications processors and limited space for power. #powerelectronics #powerdesign Link to the article: https://lnkd.in/g4EqdgyE #engineering

Follow the link below to read the recent How2Power article which features information on EPC Space's NSREC 2024 Exhibit https://hubs.li/Q02NrCPP0

SAA for LEO orbits. A good visualization that we can use to correlate potential failures or upsets for spacecraft on-orbit.

🌌 Paktron’s MLP Film Capacitors for LEO and SmallSAT Space Missions🌌 Rigorously tested to meet or exceed MIL-STD-202 requirements, our capacitors are designed for the toughest environments, offering a remarkable 25% weight reduction over equivalent MLCCs, which helps minimize satellite weight and launch costs. With an operating range from -55°C to 125°C, they ensure exceptional reliability under the extreme conditions of space. 🌡️ Key Advantages: ⭐ Rigorously tested to meet MIL-STD-202 standards ⭐ Exceptionally stable performance in varying conditions ⭐ Ultra-low ESR/ESL for optimal circuit performance ⭐ High ripple current capability ⭐NEPP tested When you choose Quantic™ Paktron, you invest in components that stand up to shock, vibration, solderability, and other stringent criteria. Elevate your projects with capacitors you can trust for mission-critical reliability! Learn More https://lnkd.in/eqEK9D9X #SpaceTech #CommercialMissions #CubeSats #SmallSats #LEO #Suborbital #QuanticPaktron #MLPFilmCapacitors #MILSTD202 #DependablePerformance

Introducing ISISPACE Group's Satellite Electrical Power System for CubeSat Missions Learn more: https://ow.ly/3OeP50QNtcv #isispace #electricalpowersystem #cubesats #leomissions #product #datasheet #quotation

Comparison of radiation hardened EPC Space GaN and Si power semiconductor device characteristics. Click the link below to learn more about this table! https://hubs.li/Q02Kdglj0 #Power #GaN #Si #PowerDevices #Space #MOSFET

Total Ionising Dose (TID) exposure in LEO orbit comes from various sources (trapped protons, trapped electrons, solar protons, secondaries). The video below illustrates the TID levels received behind 5mm of Aluminium shielding as the orbital altitude rises (the mission duration and inclination have been fixed). Higher LEO missions become increasingly challenging, particularly if COTS parts are being used. Radiation analysis and assurance should be started as early in a project as possible for feasibility assessments and to help inform part / equipment selection. Plots generated using OMERE (Trad software).

🌍📡 Today, I had the honor of attending an insightful webinar on "Mitigating Interference: The Role of Radio Regulation in Protecting Satellite Signals." The in-depth discussions and professional approaches were truly inspiring. A special thank you to: 🔹 Sitara Mehdiyeva - Head of Spectrum Management Division at Azercosmos 🔹 Aleksandr Knyazev - Leading Solutions Engineer at Azercosmos 🔹 Nadir Atayev - Senior Hardware Research Engineer, R&D at Azercosmos Thanks to their presentations, I learned so much about crucial topics such as "Satellite Utilization," "Interference," "International Frameworks," "Policy Development," and "Future Outlook." It provided me with a fresh perspective to expand my knowledge and think more deeply about innovative solutions in this field. The importance of effective radio regulation and protecting satellite signals became even clearer to me. I look forward to future developments in this area with great anticipation. 🚀📶 #Azercosmos #SatelliteSignals #RadioRegulation #InterferenceMitigation #SpaceIndustry

The PPP (Precise Point Positioning) system is a modern technology in the field of Global Positioning System (GPS) that aims to provide high accuracy in positioning, reaching centimeter or even millimeter levels. This technology is ideal for use in remote areas or locations lacking infrastructure for nearby reference stations. In this article, we will review how the PPP system works, its advantages, and its applications in various fields. How the PPP system works: The PPP system operates by receiving signals from GPS/GNSS satellites and then applying complex corrections to improve positioning accuracy. Here are the steps of the system's operation: Receiving satellite signals: The device receives signals from available GPS/GNSS satellites in the area. Error correction: Corrections are applied for errors caused by the ionosphere (the ionized layer of the atmosphere), the troposphere (the lower layer of the atmosphere), and satellite orbital deviations. These corrections are obtained from global monitoring ne