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Interstellar Technologies
Interstellar Technologies
Interstellar Technologies
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42°28′30″N 143°22′35″E / 42.47500°N 143.37639°E / 42.47500; 143.37639

Interstellar Technologies, Inc. (Japanese: インターステラテクノロジズ(株), Hepburn: Intāsutera Tekunorojizu (kabu)), or IST, is a Japanese private spaceflight company aiming to eventually build a launch vehicle for smallsats under 100 kg. It is a rocket spacelaunch company developing the MOMO [ja] (also Momo, etc.) sounding rocket and the orbital launch vehicles called ZERO [ja; fr] and DECA. Interstellar's stated goal is to reduce the cost of access to space.[1][2][3] Interstellar is attempting to have the first privately developed rocket in Japan to reach space.[4]

History

[edit]

The group that became Interstellar Technologies was created as a hobbyist organization in 1997.[5] Interstellar Technologies predecessor company was established in 2003 by Takafumi Horie, who previously founded the ISP Livedoor. It was established to develop rockets to launch small satellites. It became Interstellar Technologies in 2005 (some sources name the year 2013 as the founding year of Interstellar Technologies[6]).

In 2017, it became the first Japanese company to launch a privately developed space rocket, though the launch was unsuccessful. A subsequent test in 2019 was successful at taking a 20 kg payload on a suborbital trajectory to the edge of space. As of 2017, the company planned to develop a rocket by 2020 that would be capable of launching small satellites into orbit.[7] As of 2018, the president is Takahiro Inagawa.[2]

In March 2018, Interstellar entered into a business alliance with Nippon Travel Agency and Space Development Corp.[8] In May 2018, Interstellar received an investment of ¥19.8 million from Kushiro Manufacturing.[8]

As of June 2018, the company had raised about ¥30 million (about US$250,000) in crowdfunding.[4]

In January 2025, Interstellar received a $44 million investment from Woven by Toyota.[9]

Rockets

[edit]

MOMO sounding rocket

[edit]

The initial rocket the company is developing is the MOMO sounding rocket:

MOMO v1

[edit]

In response to the problems encountered in the engine nozzle and ignitor during the fifth launch and in the first attempt of the sixth launch (June and July 2020 respectively) Interstellar Technology began development of a full system upgrade.[13] During a video conference on June 1, 2021 they announced the end of the upgrading process that focused on engine system, airframe equipment, avionics, and ground support equipment [14] resulting in new nozzles, new ignitors, an increase in dry mass by 40 kg, in propellant mass by 30 kg, in length by 0.2 m and in thrust by 2 kN.[15] Due to the heavy modifications performed the company started referring to the previous version of the rocket as MOMO v0, while the upgraded one is now being called MOMO v1.[14]

MOMO flight testing

[edit]

The flight test program began in mid-2017:

Flight No. Date (UTC) Launch site Suborbital apogee or achieved altitude Outcome
1 30 July 2017 Taiki, Hokkaido, Japan 20 km (12 mi) Failure
Rocket failed after launch. Contact was lost 66 seconds after launch, triggering an emergency engine shutdown. The rocket reached an altitude of 20 km (12 mi). This represented the first privately funded space rocket to be launched in Japan. The launch cost about ¥50 million (US$440,000).[1][7][2][4]
2 30 June 2018 Taiki, Hokkaido, Japan Failure
Four seconds after liftoff, the rocket came crashing back down onto the pad, exploding violently.[2][4][3]
3 4 May 2019 Taiki, Hokkaido, Japan 113.4 km (70.5 mi) Success
The first commercially developed Japanese rocket to reach the Kármán line, the internationally recognized edge of space. The rocket landed in the sea.[16][17] The countdown to the launch used the singing synthesizer software Hatsune Miku.[18]
4 27 July 2019 Taiki, Hokkaido, Japan 13 km (8.1 mi) Failure
Failed (onboard computer detected a problem and shut down the engine early) shortly after liftoff. The rocket reached altitude of 13 km and fell into sea 9 km offshore. The rocket carried some experiments, for example a heat-resistant paper plane to be released from space, and a low-frequency sound sensor developed by Kochi University of Technology to observe sound created by lightning, typhoons and volcanic eruptions.[19]
5 14 June 2020 Taiki, Hokkaido, Japan 11.5 km (7.1 mi) Failure
About 35 seconds into flight, shortly after reaching max-Q, sparks were observed near the engine nozzle. About thirty seconds later, ground controllers issued an abort command which caused the rocket to tumble and fall into the ocean.[20][21]
6 3 July 2021 Taiki, Hokkaido, Japan 99 km (62 mi) Success
First flight of the improved version MOMO v1.[13] It reached an apogee of 99 km and landed in the sea 10 minutes after liftoff.[22] The rocket was named Screw Rocket by the main sponsor of the launch, Sunco Industries Co., and carried an infrasound sensor from the Kochi University of Technology.[23] A single rose from Hana-Cupid was also launched on this flight.[24] Despite the MOMO unit's number (F7), this was the sixth flight of the sounding rocket.[25]
7 31 July 2021[26] Taiki, Hokkaido, Japan[26] 92.3 km (57.4 mi) Success
Second flight of the improved version MOMO v1. Despite the MOMO unit's number (F6), this was the seventh flight of the sounding rocket. The company aimed to reach space for the third time.[27] Featuring a special, red paint job as well as the slogan "Love and Freedom and TENGA" painted on the side, the rocket was named TENGA Rocket after the sponsor, sex toy manufacturer Tenga Co., Ltd., which was also the first ever single sponsor received by Interstellar Technologies.[28] It carried out payload release and recovery mission (unknown if it was successful), the first time for a private entity in Japan. A special masturbator outfitted with sensors was launched along the rocket, aiding development of TENGA's namesake series development for use in space.[28]

ZERO orbital rocket

[edit]

The ZERO launch vehicle is aimed at orbital launches of smallsats.[29]

DECA orbital rocket

[edit]

On 25 January 2023, IST announced plans to develop the DECA launch vehicle.[32][33][34][35]

DECA is a larger launch vehicle that can build small satellite constellations, launch large satellites into orbit, and transport cargo to the International Space Station, thereby contributing to the expansion of Japan’s space transportation capabilities.[32][33][34][35] DECA will also be responsible for launching the satellite constellation targeted by the satellite developer Our Stars, a wholly owned subsidiary of IST. [32][33][34][35]

Launch site

[edit]

The launch site of IST resides next to the Taiki Aerospace Research Field of the Japan Aerospace Exploration Agency,[36] located within the Taiki Multi-Purpose Aerospace Park, which is an aerodrome in Taiki, Hokkaido, Japan.[37][2]

Launch Complex-0 (LC-0) is the launch site for MOMO and the static engine test facility for MOMO and ZERO.[37]

Launch Complex-1 (LC-1) is a new launch pad for ZERO and is planned to be available in FY2023.[37][38] LC-1 will include a Vehicle Assembly Building (VAB) and development and test facilities.[37] LC-1 will be equipped with an exhaust duct to reduce noise from the engine jet and minimize damage to the satellite from vibration.[37]

Launch Complex-2 (LC-2) is another launch pad designed for more frequent launches of ZERO and is planned to be available in FY2025.[38] LC-2 will include a Vehicle Assembly Building (VAB) capable of preparing multiple launch vehicles simultaneously.[37]

In April 2021, a plan to expand the park into a private sector spaceport, Hokkaido Spaceport [ja], was announced.[38] The current 1000-meter runway is planned to be extended to 1300 meters, and building a new 3000-meter runway is also considered.[38][39]

See also

[edit]

References

[edit]
[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Interstellar Technologies

View on Grokipedia
from Grokipedia
Interstellar Technologies Inc. is a Japanese private aerospace company founded in January 2013 in Taiki, Hokkaido, focused on developing low-cost rocket launch vehicles and satellite systems to enable frequent and affordable access to space. The company, led by CEO Takahiro Inagawa, pursues a vertically integrated business model that combines rocket manufacturing, launches, and satellite operations to integrate space infrastructure into society and address global challenges like providing high-speed broadband communications. The company's flagship sounding rocket, MOMO, marked a historic milestone as the first privately developed vehicle in Japan to reach space, achieving three successful suborbital flights: the inaugural launch on May 5, 2019, to an altitude of 110 kilometers, followed by additional successes in 2021, including a sponsored flight named the TENGA Rocket. Building on this foundation, Interstellar is advancing ZERO, a two-stage expendable orbital launch vehicle designed for small satellite deployments via dedicated missions or rideshares, with a payload capacity of up to 1,000 kilograms to low Earth orbit (250 kilograms to sun-synchronous orbit) and plans for an initial launch no earlier than 2027. Looking further ahead, DECA is a planned heavy-lift reusable rocket for the 2030s, aimed at deploying larger satellites, space telescopes, and cargo missions with significantly higher capacity and reusability features derived from ZERO's methane-propellant technology. Interstellar's achievements include securing substantial funding and partnerships to accelerate development, such as an 8.9 billion yen ($62 million) Series F round in July 2025 for ZERO and satellite R&D, a ¥4.63 billion SBIR grant from the Japanese government in September 2024 for independent space access, and strategic alliances with Germany's Exolaunch in July 2025 for rideshare services and Toyota in January 2025 for mass production at Woven City. In August 2025, the company announced its first five customer payloads for ZERO, underscoring growing demand amid global launch shortages, while in November 2025, it announced its participation in international forums like APRSAF and AP-SGW to promote Asian space collaboration. These efforts position Interstellar as a key player in Japan's burgeoning private space sector, emphasizing rapid iteration, Japanese craftsmanship, and regional expansion.

Company background

Founding and early organization

Interstellar Technologies traces its origins to 1997, when a group of university students and space enthusiasts in Japan formed the hobbyist organization "Natsu no Rocket-dan" (Summer Rocket Group), dedicated to amateur rocket experimentation and private space development. This informal collective conducted early combustion tests and rocket prototypes in fields near Taiki, Hokkaido, laying the groundwork for hands-on rocketry among non-professionals. In 2003, the group formalized into a predecessor company focused on rocket development, established by entrepreneur Takafumi Horie, whose background included founding the internet service provider Livedoor in the late 1990s. Horie's investment and involvement marked a shift toward more structured efforts in low-cost space access, building on the hobbyists' initial prototypes. The company officially incorporated as Interstellar Technologies Inc. in January 2013 in Taiki, Hokkaido, becoming Japan's first private firm dedicated exclusively to space transportation services. Headquartered in the region's aerospace-friendly environment, it emphasized agile, cost-effective innovation from its inception. Under CEO Takahiro Inagawa, who joined in 2013 and assumed leadership in 2014, the initial team comprised a small group of engineers and enthusiasts drawn from the original "Natsu no Rocket-dan" network, prioritizing rapid prototyping and minimal bureaucracy to foster breakthroughs in sounding rocket technology.

Mission, leadership, and funding

Interstellar Technologies aims to empower society through space infrastructure by developing sustainable rocket and satellite systems that address global challenges and integrate space into everyday business and daily life. The company's core mission focuses on lowering the costs of space access, enabling dedicated launches for small satellites with customer-specified orbits, and providing high-speed broadband communications via satellites for devices such as smartphones and vehicles. This vision seeks to make the wonders of space accessible to all by pioneering seamless integration of space technologies into terrestrial applications. Leadership at Interstellar Technologies is headed by CEO Takahiro Inagawa, who joined the company in 2013 and has served as CEO since 2014 and holds a master's degree in mechanical and physical engineering from the Tokyo Institute of Technology, where he contributed to satellite projects. Inagawa emphasizes vertical integration of launch vehicles and satellite systems to enhance reusability and efficiency in space operations. The executive team includes Director and Vice President of Launch Vehicle Satoshi Nakayama, Director and COO Keiji Atsuta, Director and CFO Takahiro Tsuji, Director Takafumi Horie, and external directors such as Ken Uryu and Satoshi Takechi, who bring expertise in business management and technology to support the company's focus on innovative propulsion and infrastructure development. The company's funding has grown through multiple rounds from private investors, government grants, and corporate partners, reaching a cumulative total exceeding $200 million as of November 2025, including equity and subsidies. In August 2024, Interstellar completed its Series E round with 3.1 billion yen (approximately $21 million) from investors including SBI Group, NTT DOCOMO, and Resona Capital, aimed at advancing vertical integration. This was followed in January 2025 by a 7 billion yen ($44 million) capital alliance with Woven by Toyota, marking the first close of the Series F round and focusing on reusable rocket technologies through automotive manufacturing expertise. The Series F round continued with an additional 8.9 billion yen (about $62 million) raised in July 2025 from Sumitomo Mitsui Banking Corporation and others, supporting ZERO rocket development and satellite R&D.

Historical development

Pre-incorporation efforts

The origins of what would become Interstellar Technologies began in 1997 in Hokkaido, Japan, with the formation of "Natsu no Rocket-dan" (Summer Rocket Group), a casual collective of space enthusiasts who conducted initial experiments using model rockets and rudimentary propulsion systems. These hobbyist activities focused on hands-on testing in local areas, fostering a passion for rocketry among participants who aimed to explore basic flight dynamics without formal infrastructure or funding. From 2003 to 2013, the group evolved into a more structured predecessor entity under the involvement of Takafumi Horie, the entrepreneur behind Livedoor, who established the initiative in 2003. During this phase, efforts centered on early prototyping of liquid-fuel engines, conducted through small-scale tests that did not progress to full launches, emphasizing iterative design and safety refinements. Limited resources constrained operations to amateur-level testing environments, supported primarily by volunteer engineers drawn from the original hobbyist network, which gradually shifted the group's focus from recreational pursuits to semi-professional rocketry endeavors. These pre-incorporation activities faced significant hurdles, including frequent setbacks from prototype crashes and the lack of institutional support, yet they built essential expertise in propulsion and structural integrity. The accumulated knowledge from these years directly informed the foundational designs for the MOMO sounding rocket upon the company's formal establishment in 2013.

Key milestones from incorporation to 2025

Interstellar Technologies was incorporated in 2013 in Taiki, Hokkaido, Japan, where the company established its headquarters and began setting up initial facilities at the Hokkaido Spaceport to support rocket development and testing. Over the following years, from 2013 to 2017, the firm focused on prototyping its first sounding rocket, the MOMO, leveraging the local infrastructure for engine tests and assembly to advance toward suborbital flights. The company's inaugural launch attempt occurred on July 30, 2017, when the MOMO-1 vehicle lifted off from Taiki but failed after 66 seconds due to loss of contact, triggering an emergency engine shutdown. This marked the first launch of a privately developed rocket in Japan, despite the setback. The second attempt followed on June 29, 2018, with MOMO-2, which experienced a loss of thrust just four seconds after liftoff, resulting in the vehicle's destruction shortly after launch. Progress accelerated in 2019, as MOMO-3 achieved success on May 5 (local time), reaching an apogee of 113 kilometers—the first time a privately developed Japanese rocket crossed the Kármán line into space. Later that year, on July 27, MOMO-4 launched but encountered an onboard computer anomaly after reaching 13 kilometers, falling short of its target altitude in a partial success. In 2020, MOMO-5 launched on June 13 but failed to achieve full objectives, though it demonstrated improvements in vehicle stability before falling short of space. The program rebounded in 2021 with two successful flights: on July 3, MOMO-7 reached space reliably, followed by the TENGA Rocket—a MOMO variant—on July 31, which achieved the first private payload ejection and successful recovery in Japan. By 2023, Interstellar Technologies laid groundwork for expanded orbital ambitions, announcing the DECA heavy-lift rocket concept on January 25 as Japan's first private-sector large launch vehicle, targeting service in the 2030s, while initiating preparations for a priority agreement with JAXA to support small satellite missions. In 2024, the company formalized its JAXA partnership on March 31 as a designated priority launch provider for nano-satellite procurements, and secured a ¥4.63 billion SBIR grant from the Japanese government on September 19 for independent space access development. It also raised 3.1 billion yen in Series E funding on August 5 to accelerate rocket and satellite development. Entering 2025, Interstellar Technologies announced a capital and business alliance with Woven by Toyota on January 7, involving a 7 billion yen investment to enhance manufacturing capabilities for reusable rockets. On June 12, the company signed a foundational agreement with Taiki Town, securing preferred operator status for Hokkaido Spaceport's new Launch Complex 1 to enable high-frequency launches. This was followed by a strategic partnership with Germany's Exolaunch on July 8 for rideshare services, and an additional 8.9 billion yen in Series F funding on July 10 to support ZERO rocket maturation and satellite systems. Culminating the year's advancements as of November 2025, on August 11, Interstellar revealed five customer payloads for the inaugural ZERO orbital flight, slated for 2027, and in November conducted a successful ZERO rocket engine test at Hokkaido Spaceport while participating in international forums like APRSAF and AP-SGW to promote Asian space collaboration.

Sounding rocket program

MOMO design and specifications

The MOMO sounding rocket, developed by Interstellar Technologies Inc., is a single-stage, liquid-fueled suborbital vehicle designed as a technology demonstrator for reliable propulsion systems. Measuring 10.1 meters in length and 0.5 meters in diameter, it has a total launch mass of approximately 1,220 kg, with a dry mass around 700 kg. This compact configuration enables vertical launches from the Taiki Aerospace Research Field, achieving apogees of 80–100 km for short-duration microgravity experiments, with ballistic recovery in the ocean. At its core is an in-house developed bipropellant engine utilizing liquid ethanol as fuel and liquid oxygen (LOX) as the oxidizer, operating on a pressure-fed cycle to deliver a sea-level thrust of 14 kN (equivalent to 1.4 tons-force). The engine features gimbaling for thrust vector control, supplemented by cold gas thrusters for attitude adjustments during flight. Early iterations, such as MOMO v0, produced lower thrust around 8–12 kN, but upgrades in the v1 variant—introduced in 2021—increased performance through enhancements like a silica fiber-reinforced plastic nozzle, while maintaining the overall simple architecture. This propulsion setup prioritizes ease of integration and rapid iteration, with propellant tanks constructed from lightweight composites to optimize the mass fraction for suborbital trajectories. The rocket's payload bay accommodates up to 20 kg to a 100 km apogee, supporting missions for atmospheric research, technology validation, and small-scale scientific payloads in microgravity. Key design innovations emphasize affordability and simplicity, including the use of commercial off-the-shelf components where possible to reduce development costs compared to traditional aerospace hardware, enabling frequent testing and iteration. A notable variant is the TENGA configuration, tested in 2021, which integrates a payload ejection and recovery system using parachutes for post-flight retrieval, demonstrating reusability elements for future applications. Overall, MOMO's development rationale centers on validating liquid bipropellant propulsion reliability and operational workflows in a low-cost framework, serving as a critical stepping stone for Interstellar Technologies' scalable orbital systems like the ZERO rocket. By achieving spaceflight with minimal resources—total program costs kept low through in-house manufacturing and streamlined testing—the design proves the viability of private-sector innovation in suborbital access.

MOMO flight history

The MOMO sounding rocket underwent seven test flights from 2017 to 2021, progressively validating key technologies for suborbital access while encountering challenges in guidance, structural integrity, and propulsion control. These launches, conducted from the Taiki Aerospace Research Field in Hokkaido, Japan, marked incremental advancements for Interstellar Technologies, culminating in three successful reaches to space and informing the transition to orbital vehicle development. No additional MOMO flights occurred after 2021, as resources shifted toward validating the ZERO rocket's components. The inaugural flight, MOMO F1, launched on July 30, 2017, with the primary objective of demonstrating basic ascent and engine performance. The vehicle lifted off successfully but experienced a guidance system anomaly, leading to loss of communication and an automatic termination approximately 80 seconds after ignition; it reached only about 20 km before destruct activation, providing initial data on flight termination protocols but highlighting the need for robust avionics. MOMO F2 followed on June 29, 2018, from the Taiki site, aiming to test improved structural design and ascent stability. However, an immediate post-liftoff anomaly caused the engine to shut down after just two seconds, resulting in the rocket falling back to the pad and exploding; this minimal-altitude failure (near 0 km) revealed critical structural vulnerabilities under launch loads, prompting redesigns in the airframe and ignition sequence. The third flight, MOMO F3, on May 4, 2019, sought to achieve space (above 100 km) and validate integrated engine and guidance systems. It succeeded, reaching an apogee of 113.4 km after a 515-second flight, marking the first time a privately developed Japanese rocket entered space and confirming reliable propulsion and trajectory control for suborbital missions. As a follow-on to F3, MOMO F4 launched on July 27, 2019, to gather reentry data and test payload deployment mechanisms, including experimental paper airplanes. The onboard computer detected an anomaly shortly after liftoff, triggering an early engine shutdown; the rocket achieved only 13 km altitude before crashing into the sea, yielding insights into anomaly detection but underscoring the importance of redundant flight controls. MOMO F5, on June 13, 2020, targeted another space-reaching demonstration with enhanced engine throttling. It lifted off but suffered an engine malfunction about one minute into flight, leading to loss of attitude control and a crash into the ocean at a maximum altitude of 11.5 km—well short of the 100 km goal—and emphasizing the need for improved propulsion reliability and real-time monitoring. The sixth launch chronologically, designated as the Screw Rocket (MOMO F7) on July 3, 2021, introduced the improved MOMO v1 variant to test upgraded aerodynamics and reach space reliably. It attained an apogee of 99 km, splashing down in the sea after 10 minutes, and provided data on enhanced performance that directly supported ZERO engine and guidance integration. Note that the vehicle numbering (F7) precedes the subsequent flight's F6. The seventh and final launch, designated as the TENGA Rocket (MOMO F6) on July 31, 2021, was a sponsored suborbital test focusing on payload ejection and recovery systems, in collaboration with Tenga Co. It reached an apogee of approximately 92 km (preliminary estimate), deployed payloads, and achieved parachute-assisted recovery of components—the first such demonstration by a private Japanese entity—validating commercial-sounding capabilities and microgravity experiments.

Orbital launch vehicles

ZERO development and capabilities

The ZERO rocket is a two-stage expendable launch vehicle developed by Interstellar Technologies as its primary orbital launch system for small satellites. Standing 32 meters tall with a diameter of 2.3 meters and a liftoff mass of approximately 71 metric tons, it employs liquid oxygen (LOX) and liquid methane (including biomethane sourced locally) as propellants for both stages. The first stage is powered by nine COSMOS engines, each delivering about 130 kN of thrust in a gas-generator cycle with regenerative cooling and pintle injectors, while the second stage uses a single vacuum-optimized COSMOS engine. This configuration enables payload capacities of up to 1,000 kg to a low Earth orbit (LEO), or 250 kg to a sun-synchronous orbit (SSO) at 561 km and 97.6° inclination, with orbit insertion accuracies of ±10 km in perigee, ±15 km in apogee, and ±0.1° in inclination. ZERO's capabilities center on providing dedicated launches for small satellites and CubeSats, as well as rideshare services to accommodate multiple payloads in flexible configurations, such as one primary small satellite alongside up to five CubeSats. The vehicle features a 5-meter-tall carbon fiber reinforced polymer (CFRP) fairing and non-explosive payload separation systems to minimize risks to customer hardware, supporting missions from the Hokkaido Spaceport in Taiki, Japan. It aims to offer competitive, on-demand access to space for the growing small satellite market in Asia and beyond. Static fire tests of the COSMOS engines and structural components, including propellant tanks, have been conducted progressively to validate performance. Development of ZERO began following the successful flights of Interstellar's suborbital MOMO sounding rocket, leveraging heritage in engine design and avionics to accelerate progress toward orbital capability. Key milestones include subscale engine testing in 2022, full-scale propellant tank pressure tests in early 2024, and hot-fire demonstrations of the first-stage cluster through 2024, with ongoing integration efforts. Initially targeting a maiden flight in 2025 from Launch Complex 1 (LC-1) at Hokkaido Spaceport, the timeline has been delayed to 2027 to ensure reliability, though Interstellar announced contracts for five customer payloads aboard the debut mission in August 2025. The company plans to scale to 10 launches per year post-debut to meet demand. Innovations in ZERO include a modular fairing design that allows customizable payload accommodations without major vehicle modifications, enhancing mission flexibility. All avionics for flight control, monitoring, and thrust vectoring are developed in-house using industrial-grade components to reduce costs and improve responsiveness. A January 2025 capital and business alliance with Woven by Toyota, involving a $44.3 million investment, is influencing reusability studies and manufacturing scalability, drawing on automotive production techniques for potential future enhancements, though ZERO remains fully expendable.

DECA concept and plans

DECA is a proposed multi-stage heavy-lift launch vehicle developed by Interstellar Technologies as a successor to the ZERO small-lift rocket, aimed at enabling mass transportation to space in the 2030s. The name "DECA" derives from the Greek prefix "deca," signifying a tenfold scale increase over ZERO in terms of capacity and ambition, marking the company's 10-year anniversary in 2023. It is designed to deploy small satellite constellations, launch large satellites into low Earth orbit (LEO) and other orbital regimes, and deliver cargo to space stations such as the International Space Station (ISS). The vehicle incorporates reusable technologies, particularly in the first stage, to achieve launch costs less than one-tenth of conventional rockets by leveraging innovations from the MOMO sounding rocket and ZERO orbital vehicle. Propulsion relies on liquid oxygen (LOX) paired with liquid biomethane or similar fuels, consistent with Interstellar Technologies' established engine designs. While detailed specifications remain under development, DECA targets a significantly greater payload capacity—aiming for a tenfold increase in scale over ZERO—along with enhanced reusability to support frequent, cost-effective missions. Development of DECA was formally announced on January 25, 2023, with operational service eyed for the 2030s as part of Japan's push for private-sector innovation in space transportation. Early studies and related research are supported by the company's Series F funding round, which raised an additional 8.9 billion JPY (approximately 61.8 million USD) in July 2025 from investors including . This funding bolsters broader space infrastructure efforts, including heavy-lift concepts like DECA. DECA's role extends to addressing global launch capacity shortages amid rising demand for satellite deployments and space logistics, while aligning with Japan's national objective of conducting 30 commercial launches per year to build self-sustaining space access. It further enables vertical integration with Interstellar Technologies' satellite services, such as the "Our Stars" constellation project, by providing dedicated heavy-lift capabilities for constellation buildup and resupply missions.

Facilities and operations

Launch sites and infrastructure

Interstellar Technologies primarily operates from the Hokkaido Spaceport (HOSPO), located in Taiki, Hokkaido, Japan, at the Taiki Aerospace Research Field, a facility developed in cooperation with the Japan Aerospace Exploration Agency (JAXA). The site is situated at coordinates 42°29'59.99"N, 143°26'17.39"E, benefiting from Hokkaido's expansive airspace and northern latitude, which provide favorable conditions for suborbital and orbital launches with minimal population overflight risks. Its proximity to the Pacific Ocean facilitates downrange tracking and enhances safety by allowing trajectories over open water. The infrastructure includes Launch Complex-0 (LC-0), which supports operations and features an Engine Firing Test Facility for static tests of both MOMO and vehicles. of Launch Complex-1 (LC-1) began in for orbital launches, with initial phases completed by 2023 (ending ), including foundational structures like a . LC-1 incorporates a (VAB) and planned test stands, designed for to enable rapid vehicle turnaround and assembly in a cleanroom environment that minimizes contamination risks. Propellant handling systems and two launch pads (LP11 and LP12) are under development to support liquid biomethane-fueled rockets. On June 12, 2025, Interstellar Technologies was designated as the priority launch operator for HOSPO's new facilities following a foundational agreement with Taiki Town, securing long-term access to LC-1. This status supports expansions for dedicated complexes tailored to and future DECA vehicles, aiming to accommodate over 10 launches by high-cadence operations and integration with JAXA's existing and systems at the site.

Partnerships and commercial activities

Interstellar Technologies signed a basic agreement with the Japan Aerospace Exploration Agency (JAXA) on March 26, 2024, designating the company as a priority launch provider for small satellite missions under the JAXA Small Satellite Launch Opportunities (JAXA-SMASH) program. This collaboration grants Interstellar access to national resources and positions it to support JAXA's publicly solicited nano-satellite launches, enhancing Japan's domestic space transportation capabilities. In August 2025, Interstellar announced contracts for five customer payloads aboard the maiden flight of its ZERO orbital launch vehicle, scheduled for 2027, marking the company's entry into the commercial rideshare market for small satellites. These agreements target the growing demand for affordable access to space, with payloads from diverse entities including research institutions and private firms. The company has formed key corporate alliances to bolster its technological and operational capabilities. In January 2025, Interstellar entered a capital and business partnership with Woven by , focusing on reusable rocket technologies and advanced composites to scale manufacturing for global demand. This alliance expanded in August 2025 into a three-party agreement with Motor Corporation, involving personnel support for production processes. Additionally, Interstellar participates in international forums such as the Regional Space Agency Forum (APRSAF) and the Asia-Pacific Space Generation Workshop (AP-SGW), including its announced involvement in the 31st APRSAF in November 2025, to foster regional collaborations and innovation. Interstellar's business strategy emphasizes , combining rocket launches with satellite communications services to create a comprehensive space infrastructure ecosystem—the first such model in Japan. This approach aims to capture a portion of the market dominated by providers like , particularly in response to the global launch shortages, where the conducted 158 orbital launches and 68, highlighting opportunities for small satellites.

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  25. https://space.skyrocket.de/doc_lau/momo.htm
  26. https://www.space.com/41056-japan-private-rocket-launch-explosion.html
  27. https://www.istellartech.com/en/launch/momo
  28. https://www.istellartech.com/en_news/7929
  29. https://www.istellartech.com/en_news/8623?category=RELEASES
  30. https://www.istellartech.com/en_news/9675
  31. https://www.istellartech.com/en_news/10064
  32. https://www.exolaunch.com/news_133.html
  33. https://spacelaunchnow.me/vehicle/launch_vehicle/198
  34. https://rocketlaunch.org/launch-providers/interstellar-technologies/momo-v1
  35. https://digitalcommons.usu.edu/cgi/viewcontent.cgi?article=6054&context=smallsat
  36. https://spectrumlocalnews.com/nys/watertown/ap-top-news/2019/05/04/japans-private-rocket-reaches-outer-space-for-first-time
  37. https://rocketlaunch.org/launch-providers/interstellar-technologies
  38. https://phys.org/news/2018-07-interstellar-technologies-rocket-momo-failure.html
  39. https://newsonjapan.com/article/125318.php
  40. https://phys.org/news/2019-07-japanese-startup-gears-fourth-rocket.html
  41. https://www.space.com/interstellar-technologies-momo-f5-rocket-launch-failure.html
  42. https://techcrunch.com/2020/06/13/interstellar-technologies-privately-developed-momo-5-rocket-falls-short-of-reaching-space/
  43. https://spacelaunchnow.me/launch/momo-flight-7/
  44. https://www.spacelaunchschedule.com/launch/momo-flight-7/
  45. https://www.istellartech.com/7hbym/wp-content/uploads/2021/08/f64e1c6d8e4e6d1786b0d8e54ee6cb9d.pdf
  46. https://www.istellartech.com/7hbym/wp-content/themes/ist_2023/assets/pdf/usersguide_zero.pdf
  47. https://www.istellartech.com/en_news/8623
  48. https://www.istellartech.com/en_news/7933
  49. https://payloadspace.com/interstellar-books-customers-for-its-first-zero-launch/
  50. https://www.compositesworld.com/news/toyota-invests-in-interstellar-enters-reuseable-launch-rocket-market
  51. https://www.istellartech.com/7hbym/wp-content/uploads/2023/01/20230125_Japans-First-Private-Sector-Large-rocket-Launch-Vehicle-_DECA_.pdf
  52. https://forum.nasaspaceflight.com/index.php?topic=42521.660
  53. https://global.jaxa.jp/about/centers/taiki/index.html
  54. https://latitude.to/articles-by-country/jp/japan/226507/taiki-aerospace-research-field
  55. https://www.41nbc.com/community-prepares-students-return/?s-news-981778-2025-10-15-firefly-eyes-global-expansion-hokkaido-spaceport-mou-alpha-launch
  56. https://hokkaidospaceport.com/en/facilities/
  57. https://hokkaidospaceport.com/en/news/899
  58. https://www.istellartech.com/en/launch/launch-complex
  59. https://hokkaidospaceport.com/en/news/1916
  60. https://www.istellartech.com/7hbym/wp-content/uploads/2024/03/20240326_Interstellar-Technologies-Selected-by-JAXA-as-Priority-Launch-Provider-Signs-Basic-Agreement.pdf
  61. https://spacenews.com/jaxa-selects-interstellar-technologies-as-priority-launch-provider/
  62. https://www.istellartech.com/en_news/8728
  63. https://www.istellartech.com/en_news/10168
  64. https://www.istellartech.com/news/event/10929
  65. https://payloadspace.com/2024-orbital-launch-attempts-by-country/
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