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Space laser transmission strikes Earth from 140 million miles away: NASA "This achievement provides a glimpse into how spacecraft could use optical communications in the future, enabling higher-data-rate communications of complex scientific information as well as high-definition imagery and video in support of humanity’s next giant leap: sending humans to Mars." "NASA wanted to show the potential for laser communications to be conducted across interstellar distances, allowing for high bandwidth and a much speedier connection — from 10 to 100 times faster than what’s available today — between humans and the probes they send into space." https://lnkd.in/ex4uRCP3 #nasa #templartitannews

NASA's upcoming test of deep space optical communications promises higher data transmission rates compared to traditional RF methods. This innovation will transform data transmission in space to enable faster and more efficient communication. This aligns with our commitment to advancing RF technology. How do you think deep space optical communications will change the future of space missions?  Discover the full details of this revolutionary technology in the article. #NASA #OpticalCommunications #DataTransmission #RFMethods #RFTechnology #QMicrowave

"Onboard computers are critical to space exploration, aiding nearly every spacecraft function from propulsion and navigation systems to life support technology, science data retrieval and analysis, communications, and reentry. But computers in space are susceptible to ionizing solar and cosmic radiation. Just one high-energy particle can trigger a so-called "single event effect," causing minor data errors that lead to cascading malfunctions, system crashes, and permanent damage. NASA has long sought cost-effective solutions to mitigate radiation effects on computers to ensure mission safety and success. Enter the Radiation Tolerant Computer (RadPC) technology demonstration, one of 10 NASA payloads set to fly aboard the next lunar delivery for the agency's CLPS (Commercial Lunar Payload Services) initiative. RadPC will be carried to the moon's surface by Firefly Aerospace's Blue Ghost 1 lunar lander." #spacecomputers #radiationprotection

NASA’s optical communications demonstration has shown that it can transmit test data at a maximum rate of 267 megabits per second (Mbps) from the flight laser transceiver’s near-infrared downlink laser — a bit rate comparable to broadband internet download speeds. That was achieved on Dec. 11, 2023, when the experiment beamed a 15-second ultra-high-definition video to Earth from 19 million miles away (31 million kilometers, or about 80 times the Earth-Moon distance). The video, along with other test data, including digital versions of Arizona State University’s Psyche Inspired artwork, had been loaded onto the flight laser transceiver before Psyche launched last year. Now that the spacecraft is more than seven times farther away, the rate at which it can send and receive data is reduced, as expected. During the April 8 test, the spacecraft transmitted test data at a maximum rate of 25 Mbps, which far surpasses the project’s goal of proving at least 1 Mbps was possible at that distance. The project team also commanded the transceiver to transmit Psyche-generated data optically. While Psyche was transmitting data over its radio frequency channel to NASA’s Deep Space Network (DSN), the optical communications system simultaneously transmitted a portion of the same data to the Hale Telescope at Caltech’s Palomar Observatory in San Diego County, California — the tech demo’s primary downlink ground station. “After receiving the data from the DSN and Palomar, we verified the optically downlinked data at JPL,” said Ken Andrews, project flight operations lead at JPL. “It was a small amount of data downlinked over a short time frame, but the fact we’re doing this now has surpassed all of our expectations.” #NASA #DSOC #Psyche This visualization shows the Psyche spacecraft’s position on April 8 when the DSOC flight laser transceiver transmitted data at a rate of 25 Mbps over 140 million miles to a downlink station on Earth. (NASA/JPL-Caltech)

Voyager 1, launched in 1977, has overcome a recent technical glitch and restored full data transmission from its four scientific instruments after months of downtime.[1] Despite being over 24 billion km (15 billion miles) from Earth, NASA engineers managed to locate a faulty chip causing data corruption, and reconfigured the onboard software to bypass the affected memory areas.[1][5] This remarkable feat, achieved through a painstaking dialogue with the 46-year-old spacecraft, highlights the ingenuity and perseverance of the Voyager team. While cutting-edge technologies like SpaceX's Starship may capture public imagination, the plasma waves and magnetic fields studied by Voyager 1 in deep space are equally vital for advancing our scientific understanding.[1] The successful recovery of Voyager 1's operations is a testament to the enduring legacy of this pioneering mission and the dedication of its engineers, who continue to push the boundaries of space exploration. Sources [1] NASA’s Voyager 1 Restores Full Data Transmission After Months-Long Hiatus https://lnkd.in/dupj3RuT [2] Voyager-1 sends readable data again from deep space - BBC https://lnkd.in/dKsMVNdG [3] Voyager 1 sends back surprising response after 'poke' from NASA https://lnkd.in/dMitQqHS [4] Voyager 1 - NASA Blogs https://lnkd.in/dqxPek5a [5] Voyager 1 is sending data back to Earth for the first time in 5 months https://lnkd.in/dPQCja_V [6] We finally know why NASA's Voyager 1 spacecraft stopped ... https://lnkd.in/dG-7dv_d

As of now, Voyager 1 is over 23.8 billion kilometers (about 14.8 billion miles) away from Earth, making it the farthest human-made object in space. This immense distance poses significant challenges for communication, but Voyager 1 continues to send data back to Earth through a few key technologies: 1. Radio Waves: -Communication: Voyager 1 uses a high-gain antenna to send and receive radio signals. These signals travel at the speed of light, taking over 21 hours to reach Earth due to the vast distance. 2. Deep Space Network (DSN): -Global Array : NASA's Deep Space Network (DSN) consists of large antennas located in California, Spain, and Australia. These antennas are specially designed to communicate with distant spacecraft. -Signal Processing : The DSN's powerful antennas can detect the faint signals sent by Voyager 1. Advanced signal processing techniques help in enhancing the quality and clarity of these signals. 3. Power Supply: -Radioisotope Thermoelectric Generators (RTGs) : Voyager 1 is powered by RTGs, which convert heat from the natural decay of plutonium-238 into electricity. This power supply allows the spacecraft to operate its instruments and communication systems even in the far reaches of space. 4. Data Transmission: -Low Data Rate : Due to the long distance, the data transmission rate is very low, currently around 160 bits per second. However, this is sufficient to send valuable scientific data back to Earth. -Data Compression : The spacecraft uses data compression techniques to maximize the amount of information that can be sent with the limited bandwidth. Voyager 1's continued ability to communicate with Earth is a testament to the ingenuity of its design and the robustness of the Deep Space Network. It's truly an incredible achievement in space exploration! 2/2

New Post: NASA to Test Solution for Radiation-Tolerant Computing in Space - https://lnkd.in/e7izA3qF computers are critical to space exploration, aiding nearly every spacecraft function from propulsion and navigation systems to life support technology, science data retrieval and analysis, communications, and reentry. But computers in space are susceptible to ionizing solar and cosmic radiation. Just one high-energy particle can trigger a so-called “single event effect,” causing minor data …

New Post: NASA to Test Solution for Radiation-Tolerant Computing in Space - https://lnkd.in/e7izA3qF computers are critical to space exploration, aiding nearly every spacecraft function from propulsion and navigation systems to life support technology, science data retrieval and analysis, communications, and reentry. But computers in space are susceptible to ionizing solar and cosmic radiation. Just one high-energy particle can trigger a so-called “single event effect,” causing minor data …

NASA Trials Radiation-Resistant Computing Technology for Space Missions Innovative Computer Technology Aims to Enhance Space Exploration The realm of space exploration is as vast as it is complex, with onboard computers playing a pivotal role in almost every aspect of a spacecraft’s journey. From controlling propulsion and navigation systems to managing life support, retrieving and analyzing scientific data, handling communications, and ensuring safe reentry, these computers are the unsung heroes of space missions. However, they face a significant challenge that comes from beyond our planet: ionizing solar and cosmic radiation. This radiation can cause a phenomenon known as a “single event effect,” where a high-energy particle disrupts the […] https://lnkd.in/dTZfZuv6 https://lnkd.in/dgRUvNw7

NASA to Test Solution for Radiation-Tolerant Computing in Space Onboard computers are critical to space exploration, aiding nearly every spacecraft function from propulsion and navigation systems to life support technology, science data retrieval and analysis, communications, and reentry. But computers in space are susceptible to ionizing solar and cosmic radiation. Just one high-energy particle can trigger a so-called “single event effect,” causing minor data […]