Internet Engineering Task Force M. Blanchet Internet-Draft Viagenie Intended status: Informational W. Eddy Expires: 20 December 2025 MTI Systems M. Eubanks Space Initiatives Inc 18 June 2025 IP in Deep Space: Key Characteristics, Use Cases and Requirements draft-many-tiptop-usecase-03 Abstract Deep space communications involve long delays (e.g., Earth to Mars has one-way delays 4-24 minutes) and intermittent communications, mainly because of orbital dynamics. The IP protocol stack used on the Internet is based on the assumptions of shorter delays and mostly uninterrupted communications. This document describes the key characteristics, use cases, and requirements for deep space networking, intended to help when profiling IP protocols in such environment. Status of This Memo This Internet-Draft is submitted in full conformance with the provisions of BCP 78 and BCP 79. Internet-Drafts are working documents of the Internet Engineering Task Force (IETF). Note that other groups may also distribute working documents as Internet-Drafts. The list of current Internet- Drafts is at https://datatracker.ietf.org/drafts/current/. Internet-Drafts are draft documents valid for a maximum of six months and may be updated, replaced, or obsoleted by other documents at any time. It is inappropriate to use Internet-Drafts as reference material or to cite them other than as "work in progress." This Internet-Draft will expire on 20 December 2025. Copyright Notice Copyright (c) 2025 IETF Trust and the persons identified as the document authors. All rights reserved. This document is subject to BCP 78 and the IETF Trust's Legal Provisions Relating to IETF Documents (https://trustee.ietf.org/ license-info) in effect on the date of publication of this document. Blanchet, et al. Expires 20 December 2025 [Page 1] Internet-Draft IP in Deep Space June 2025 Please review these documents carefully, as they describe your rights and restrictions with respect to this document. Code Components extracted from this document must include Revised BSD License text as described in Section 4.e of the Trust Legal Provisions and are provided without warranty as described in the Revised BSD License. Table of Contents 1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 2 1.1. Limitations of this document . . . . . . . . . . . . . . 3 1.2. Terminology . . . . . . . . . . . . . . . . . . . . . . . 4 1.3. Document and Discussion Locations . . . . . . . . . . . . 4 2. Characteristics . . . . . . . . . . . . . . . . . . . . . . . 4 2.1. Common Aspects . . . . . . . . . . . . . . . . . . . . . 5 2.2. Moon . . . . . . . . . . . . . . . . . . . . . . . . . . 7 2.3. Mars . . . . . . . . . . . . . . . . . . . . . . . . . . 8 2.4. Lagrange Points . . . . . . . . . . . . . . . . . . . . . 9 2.5. Cruising Spacecraft . . . . . . . . . . . . . . . . . . . 9 2.6. Spacecraft Onboard . . . . . . . . . . . . . . . . . . . 10 3. Use Cases . . . . . . . . . . . . . . . . . . . . . . . . . . 10 4. Requirements . . . . . . . . . . . . . . . . . . . . . . . . 12 4.1. Store-and-Forward . . . . . . . . . . . . . . . . . . . . 12 4.2. Time . . . . . . . . . . . . . . . . . . . . . . . . . . 13 4.3. Signaling and Exchanges . . . . . . . . . . . . . . . . . 14 4.4. Bandwidth . . . . . . . . . . . . . . . . . . . . . . . . 14 4.5. Transport . . . . . . . . . . . . . . . . . . . . . . . . 14 4.6. Addressing and Routing . . . . . . . . . . . . . . . . . 15 4.7. Recovery on Reboot . . . . . . . . . . . . . . . . . . . 15 5. Security Considerations . . . . . . . . . . . . . . . . . . . 15 6. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 16 7. References . . . . . . . . . . . . . . . . . . . . . . . . . 16 7.1. Informative References . . . . . . . . . . . . . . . . . 16 Acknowledgements . . . . . . . . . . . . . . . . . . . . . . . . 18 Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 19 1. Introduction Deep space communications involve long delays (e.g., Earth to Mars is 4-24 minutes one way) and intermittent communications, mainly because of orbital dynamics. Up to now, communications have typically been done on a layer-2 point to point basis, in some cases with relays operating at layer-2 or below. Most missions have operated on their own, without direct data exchanges between spacecrafts at higher layers. Use of networking technologies, including IP, has become established within space vehicles that have their own onboard networks. Complex human exploration and collaborative science missions are driving Blanchet, et al. Expires 20 December 2025 [Page 2] Internet-Draft IP in Deep Space June 2025 increased networking between vehicles. Additionally, there is a rising need for interoperability between mission end-users and multiple service providers. As the scale of missions, link interconnections, and application interactions grows, it will be increasingly important to support standard IP-based network data flows. This document describes the key characteristics and use cases for networking in deep space. It provides examples taken from the current communications facilities to reach the Moon and Mars, as well as future plans. While these examples provide great insight on what is possible today, the resulting architecture should also consider future possibilities and farther celestial bodies. For example, while the number of relays and orbiters around the Moon and Mars is currently limited, it is expected that their number will increase significantly, therefore providing improved coverage around those celestial bodies, resulting in an impact on communications and networking traffic patterns, intermittence and alternate paths. Initially the needs considered in this document are to support IP- based applications in or between private networks, without assumption of reachability to/from the global Internet. At least initially, interplanetary IP networks are likely to be protected from the Internet, and vice-versa the Internet is protected from them (since they may have unique routing, congestion control, and other behaviors). However, over time it is possible that connectivity to the Internet may become available for some mission assets, and eventually interplanetary networks could become part of the Internet. This work is a followup of an assessment on the use of the IP protocol stack in deep space [I-D.many-deepspace-ip-assessment]. 1.1. Limitations of this document Communication in deep space is vastly different than on Earth. This document does not describe space communication technologies below IP, but only the information relevant from the IP protocol stack viewpoint for the purpose of its engineering. More information is available for the Moon [ioagmoon] and Mars [ioagmars]. Position, Navigation and Timing (PNT) is not directly discussed in this memo, but is a vital offering from space network service providers, in addition to data communications. Networking can support some of the data exchanges that facilitate PNT services. Near Earth orbits, such as Low Earth Orbit (LEO), Medium Earth Orbit (MEO), and Geosynchronous Earth Orbit (GEO) communications and networking to and from Earth are out of scope for this memo. Blanchet, et al. Expires 20 December 2025 [Page 3] Internet-Draft IP in Deep Space June 2025 However, given the relatively small distance to the Moon, there are possibilities to use spacecraft around Earth or at Lagrange points as relays to communicate with lunar assets. In this context, these possibilities are in scope. 1.2. Terminology * Deep space: while the ITU definition [deepspacewikipedia] of deep space is beyond 2 million km, in this document, the Moon and its environs are included since networking for this regime bears more similarities to other deep space bodies than to terrestrial and Earth-orbiting conditions. * Direct-with-Earth (DWE): communications from/to a spacecraft directly to/from Earth, without the use of relays. * Moon, Lunar: refers to Earth's Moon. * Deep Space Network (DSN): NASA’s international array of giant radio antennas that supports interplanetary spacecraft missions [DSN]. * LunaNet Service Providers (LNSP): service providers to the lunar surface and orbital regions, including private commercial operators, as defined in the LunaNet Interoperability Specification [lnis]. 1.3. Document and Discussion Locations The source of this document is located at https://github.com/marcblanchet/draft-tiptop-usecase. Comments or changes are welcomed by filing a PR or an issue against that repository. This subject should be discussed on the IETF tiptop working group mailing list. 2. Characteristics Compared to Internet on Earth, deep space communications and networking have multiple challenges, such as: * Significant and variable delays (e.g. round trips of multiple seconds, minutes, or hours). * Frequent and long interruptions of communications, often with no alternate path. Because of orbital dynamics, a spacecraft may not be reachable from Earth because it is occluded by a celestial Blanchet, et al. Expires 20 December 2025 [Page 4] Internet-Draft IP in Deep Space June 2025 body. However, spacecraft location and reachability can be generally precalculated so that the communication windows can be planned between pairs of spacecraft or between a spacecraft and a celestial body such as Earth, Moon or Mars. * Lower bandwidth, sometimes even measured in "bits per second" rather than typical terrestrial Mbps and Gbps rates. * One-way / unidirectional links are sometimes used. * Highly asymmetrical bandwidth and data rates are often present between uplink (DWE to a spacecraft) and downlink (DWE from a spacecraft), due to varying transmission power levels, antenna sizes, and other physical link properties. * Limited onboard computing resources can lead to simplified or streamlined protocol implementations. * Limited energy supply can further reduce contact opportunities and performance. Without any changes, a typical Internet application will not work in this environment, though some Internet stack protocols are more suitable than others. Among the challenges in this list, the primary factors impacting Internet stack protocols are delays and disruptions, discussed in this memo. This section describes the following cases of mission operating environments: Moon (surface and orbiting), Mars (surface and orbiting), Lagrange points, cruising spacecraft, and onboard spacecraft, starting with some commonality between all cases. 2.1. Common Aspects Various CCSDS link-layer protocols, such as Telecommand (TC) [CCSDS_TC], Telemetry (TM) [CCSDS_TM], Advanced Orbiting Systems (AOS) [CCSDS_AOS], and Proximity1 (Prox1) [CCSDS_PROX1] are used on the links between Earth, orbiters and surface assets. A newer Unified Space Data Link Protocol (USLP) [CCSDS_USLP], has been designed to replace these in the future. A generic encapsulation mechanism is defined by CCSDS to support networking and other uses over these link layer protocols, including IPv4, IPv6, and IP header compression options [IPoverCCSDSSpaceLinks][SANAIPEHeaderRegistry]. IP packets can be transported over any CCSDS link layers. Surface assets on celestial bodies, such as habitats, rovers, stations and others may communicate with each other while on the surface network using Earth terrestrial technologies such as IEEE Blanchet, et al. Expires 20 December 2025 [Page 5] Internet-Draft IP in Deep Space June 2025 802.11 and 3GPP technologies [ioagmoon][ioagmars] using IP, similar to the Internet, where links are almost always connected and there are no significant delays. They may also communicate using a relay orbiter. Multiple providers, such as the LNSPs for the Moon, will provide various services including communications and networking. Orbiters acting as communications relays are already deployed or planned for both the Moon and Mars. A sufficient number of orbiters can create a constellation which may provide full coverage of the celestial body surface [ioagmoon][ioagmars], or at least key regions (e.g. the lunar south pole). Relaying from one surface asset to another surface asset through these orbiters may use either CCSDS link-layers or link-layers similar to LEO constellations on Earth. Space missions are typically planned many years in advance and are long-lived, spanning over many years or decades. Spacecraft are controlled from Earth and therefore should always be manageable from Earth. Given the remoteness and the difficulty to physically access the spacecraft, software upgrades and configuration changes are avoided whenever possible and backward compatibility is paramount. Space exploration is more than ever carried by multiple stakeholders. A mixture of assets operated by government, commercial, and academic/ research organizations from multiple nations are deployed. They will operate largely independently, but collaboration over time is expected to meet shared science goals, joint exploration missions, and mission cross-support needs (e.g. in contingency and emergency cases). While links can be noisy due to weak signals, interference, etc., often packet delivery is actually virtually error-free due to the strong coding available within the link layer. Delivery is generally in-order. Queuing in modems, gateways, and other systems may be significant in comparison to typical terrestrial device queues. In some planetary proximity regimes, CCSDS COP-1 or COP-P link layer retransmissions may be performed, further improving reliability at the IP layer (at some expense to delays). Packet losses might be more common in some specific cases of either very low link margins or aggressive Adaptive Coding and Modulation (ACM), even though they might generally be avoided through physical link engineering and contact planning. Blanchet, et al. Expires 20 December 2025 [Page 6] Internet-Draft IP in Deep Space June 2025 2.2. Moon There are currently very few orbiters around Moon but there are plans to establish multiple constellations of them to be used as communication relays. As few as 5 cooperating orbiters at the right orbits is sufficient to provide full coverage [ioagmoon], and smaller sets of orbiters can be targeted to provide full coverage of specific limited regions such as the far side or the polar regions [imconstellation]. Until full coverage is accomplished, interruptions of communications are expected. While Earth ground stations are able to directly cover assets on the near side of Moon, use of relays may still be desirable to improve power usage, data capacity, and spectrum efficiency. Different types of networking nodes are expected on the lunar surface, with a wide range of capabilities, from those that have very limited functionality (similar to IoT devices on Earth), up to more highly-capable infrastructure hub nodes that provide access for other surface users (e.g. in a habitat or lander), and in-between cases such as crewed or uncrewed rovers that may have combinations of direct-to-Earth, with proximity orbiters, or via local wireless LAN or cellular capabilities. The LunaNet Interoperability Specification (LNIS) [lnis] is a framework including IP networking support for lunar service providers and users to acheive interoperability. For human / crewed operations, nearly continuous coverage and data flows might be expected. However, for other types of network users (such as science missions), only limited communication opportunities may be available. Some nodes (such as those supporting human missions) may have multiple/redundant links available simultaneously, but this should not be expected in general, and even then it is likely to be more for failover use than for multipath network transport. Data link operation is scheduled in advance through coordination between the end-user mission operations centers and LNSPs. The time windows for operation and data rates are well-known in advance (typically days or more). Successful link operation generally requires both directional pointing/tracking (with knowledge of vehicle locations and motion) of antenna systems, as well as pre- configuration of modem / signal processing and gateway systems that require prior coordination on many parameters. Ad hoc or random access may be available at some later point, but is likely to be rare for at least proximity and direct-with-Earth links. Blanchet, et al. Expires 20 December 2025 [Page 7] Internet-Draft IP in Deep Space June 2025 Near or on the surface, it is currently expected that the mobile spacecraft such as rovers or humans will be moving slowly compared to fast-moving vehicules on terrestrial networks where specific requirements are needed for handover. While interoperability and cross support are frequently expected, there is no assumption in-general that different parties can simply connect at the link layer or trade packets at the network layer (either directly or through intermediaries). Network routing and interconnection is likely to be closely coordinated and limited by policies established jointly between cooperating organizations. It is not likely to be directly like the Internet, with BGP, DNS, etc. generally available to support interdomain operations. One-way delay from Earth to Moon is around 1.3 seconds. Capacity is expected to eventually be in the range of hundreds of Mbps over radio links and Gbps via optical links between Earth and Moon assets [ioagmoon]. 2.3. Mars There are currently some orbiters around Mars, of which 4 are actively in use as relays, and 2 active rovers. Multiple missions are planned[ioagmars] in the coming years. Communications are from ground stations on Earth, such as the DSN, to Mars orbiters acting as layer0-1 relays to surface assets such as rovers, and reverse. The relays do not have notion of frames, and only forward bits at different frequencies for each segment, a mechanism named "bag of bits"[ioagmars]. These orbiters can do as "bent-pipe" when the two segments are active, or by storing the bits as "store-and-forward" until the next segment becomes available. Since the current set of orbiters do not provide full coverage of Mars, the communication windows are calculated and planned between Earth and each orbiter, and between each orbiter and each surface asset. Currently, only one rover can use a relay link at any given time. The MaROS project[maros] sponsored by the Jet Propulsion Laboratory acts as a broker to enable missions to enter data about the communications capabilities such as frequencies, bandwidth, window of communication time, ... so that rover missions can schedule the available communications windows for transmitting and receiving. Most orbiters are used and scheduled in MaROS. One of the Mars orbiters is Mars Reconnaissance Orbiter(MRO)[mro]. It was launched in 2005 and has a single 40Mhz processor but over 100G of solid state memory. MaROS experience over years shows that the current bottleneck is not the temporary storage of the relays but the bandwidth from Mars surface assets to Mars orbiter relays. As demonstrated by a study[marscommstudy] on Mars communication windows, the communication Blanchet, et al. Expires 20 December 2025 [Page 8] Internet-Draft IP in Deep Space June 2025 windows seem to happen at a constant frequency, but the reality shows that the timing is pretty variable, which means a very large range of resulting round-trip time (RTT) for communications from Earth to Mars and back. For example, within 3 months in 2024, the calculated RTT of the various combinations of orbiters and rovers varied from 30 minutes to 170 hours. Surface assets are commanded directly from Earth but at a very low rate. The traffic from the assets to Earth goes through relays. It is expected that future constellations of Mars orbiters acting as relays will also have optical inter-satellite links[ioagmars]. The current orbiters were put in various orbits for the purpose of science, and usually have a small number of short relay opportunities per day. However, dedicated relay orbiters could be put at much higher altitudes to provide much better coverage. About every two years, a solar conjunction happens for a period of around 2 weeks, where the Sun is between Earth and Mars, therefore causing the interruption of communications between Earth and Mars. One-way delay from Earth to Mars is from 4 to 24 minutes, depending on the actual relative distance between them. It is envisioned that optical links between Earth and Mars may deliver hundreds of Mbps[ioagmars]. 2.4. Lagrange Points Sun-Earth and Earth-Moon Lagrange points, such as Earth-Moon (EML)- 1,2,4,5 and Earth-Sun (ESL)-1,2, are popular for science mission objectives and also being considered for communication relays and therefore potential network forwarders. Sets of cooperating spacecraft may also be used to increase data return and streamline operations for science missions co-located at Lagrange points, by networking locally and sharing a common DWE "trunk link". 2.5. Cruising Spacecraft Spacecraft that are cruising towards a deep space destination are assumed to generally be reached via direct point-to-point links from Earth using CCSDS link-layers. Blanchet, et al. Expires 20 December 2025 [Page 9] Internet-Draft IP in Deep Space June 2025 2.6. Spacecraft Onboard Modern spacecraft generally contain multiple computers typically linked with wired realtime buses or links such as CAN, SpaceWire, RS- 422, and others, but also increasingly using Ethernet or Time- Triggered Ethernet [tte] (TTE), with IP as the networking layer. Especially in complex human-crewed vehicles, WiFi is becoming important, and has been used extensively in the International Space Station and planned for the Lunar Gateway. IP networking onboard a spacecraft (or within a habitat) can support applications within the local network, without experiencing most of the typical space communications challenges described prior. Considerations need to be made, however, in order to make sure these applications do not rely on typical wider infrastructure (e.g. DNS, NTP, etc.) that may not be externally available in space. Additionally, some nodes on the network may be mobile/dynamic, such as astronaut suits and personal electronics, rovers, etc. 3. Use Cases Multiple countries are developing systems aimed for a sustained lunar presence combining crewed and robotic missions. The technologies developed for lunar use are intended to be applied later for Mars as well, and might equally apply for missions to asteroids and other deep space bodies. IP has been included in the stack for the International Deep Space Interoperability Standards [idsis], and the LunaNet Interoperability Specification [lnis]. There is a general intention to extend and reuse systems developed for lunar use to later Mars use. Separate space agencies and private companies are deploying lunar space stations, orbiters, landers, rovers, habitats, crewed mission elements, and other assets. Due to pervasive use and support of IP in modern computing systems, it is used onboard many space systems already, and between co-located systems (e.g. onboard ISS), and planned to be needed for networking on the Lunar Gateway, in Lunar 3GPP surface networks, and in Lunar habitat LAN and WLAN networks. As more-and-more IP-enabled assets become deployed in lunar vicinity, it will increasingly create opportunities to interconnect them. In fact, internetworking of lunar (and future Mars) systems is becoming essential, as plans call explicitly for cooperation between mission elements and communications/navigation system assets operated by different space agencies and/or private companies acting as service providers. Blanchet, et al. Expires 20 December 2025 [Page 10] Internet-Draft IP in Deep Space June 2025 There are expected to be several different interoperable LNSPs offering a variety of relay and/or DWE services, to provide wide coverage and cross-support opportunities. As more significant numbers of missions target Mars and other bodies, the same concepts should apply. It may be expected that planetary IP networks should over time become united into larger aggregates, and even into a single interoperable network (as intended within the LunaNet conception). It is expected that surface assets (for Moon, Mars, asteroids, etc.) will communicate with other surface assets on the same body through typical Earth-based wireless technologies such as WiFi or 4G/5G/6G, or via a orbiting relays. Regarding applications, the following is an incomplete list: * Telecommand: Commanding can take different forms, either individual commands or batching commands together. Individual commands sent to a mission/spacecraft from Earth are typically small (may fit within a single packet in many cases), and should typically be received reliably and in-order to be processed. Commands with dependencies or other relations may be grouped together for transmission and to help assure coherent execution rather than sent individually. This can resemble small file transfer, for instance. Commands may be time-sensitive, or have an "expiration date" after which they are not useful to store/ carry in the network. Required data rates may typically be in kbps and bursty. * Telemetry: Spacecraft stream telemetry data (periodically measured onboard status, metrics, etc.) to Earth for monitoring and other purposes. Timely delivery is useful, but storage in the network is fine, if needed. Required data rates may be approaching the Mbps range, and often a constant/steady stream of data is produced. * On-demand/real-time media(audio, video, ...): when a active path from the asset to Earth, the asset sends a media feed. The delay is only the propagation delay. * Delayed media: the asset sends the media, but it is expected that there is no active path from the asset to Earth, so data may be temporarily stored in the network. * Emergency and Search and Rescue (SAR) messaging: sent from an asset to one or many other assets (e.g. via broadcast or multicast) that support emergency operations. Since crew or Blanchet, et al. Expires 20 December 2025 [Page 11] Internet-Draft IP in Deep Space June 2025 mission safety may be at risk, this traffic should be prioritized over most other types of packets when encountering queuing or storage within the network. Timely delivery is necessary, but it should also be delivered reliably. * Science data: Typically science data may take the form of large bulk file transfers unicasted from a spacecraft to Earth. In many cases, storage and large delays in delivery can be tolerated. File transfer applications such as CCSDS File Delivery Protocol (CFDP)[CCSDS_CFDP] are typically used, that might be configured to either operate unidirectionally or may provide reliability through retransmissions, and require at least small amount of feedback. Some science applications may also use messaging patterns to collaborate between different types of instruments in order to draw attention to events (e.g. gamma ray bursts, etc.) and bring different types of instruments to bear. These messages may need to be quickly delivered and/or multicasted. * Messaging: Many different types of machine-to-machine messaging need to be supported, including for uses such as (1) providing PNT data/measurements to feed positioning, orbit determination, and time transfer or clock calibration, (2) providing space weather alerts, (3) providing advisory or other network information (e.g. almanac data such as ephemeris data for relay and other network elements, scheduled future contacts, or other service management related messaging). Messages are generally small (though may vary depending on type) and might be unicast, broadcast, or multicast. In cases where they are advisory, for instance, they may not need reliable transport, though often it will be important to provide timely transmission. * Network and Asset management: sending requests and getting answers from assets about their overall status, status of their components, energy levels, storage capacities, etc. 4. Requirements 4.1. Store-and-Forward Until full coverage by orbiter constellations is achieved around a celestial body, the orbiters and other assets that are facing intermittent communications should provide store-and-forward capability. These can be implemented at - layer-1, like the current Mars orbiters, where frames are not seen ("bag of bits"), at layer-2 doing frame storage or at layer-3 doing packet storage. Storage higher in the stack enables more versatile, agile and policy-based routing. A key factor for designing the store and forward capability of an orbiter is its storage capacity. Blanchet, et al. Expires 20 December 2025 [Page 12] Internet-Draft IP in Deep Space June 2025 Surface assets that are facing intermittent communications also need the store-and-forward capability. Mechanisms should be defined to avoid as much as possible storage full events on a relay. This may include some in-advance signaling to the network about future full storage event, so that the network and/or the source can throttle down or reroute packets to avoid that event. In the event of full storage, a policy should be determined on which packets should be dropped, such as the last one in the queue, the first one in the queue, ones based on policies related to packet or transport fields like source or destination addresses, traffic classes, flow ids, etc. , similar to queue management used in terrestrial networks. These policies are important for differentiated trafic such as Emergency and Search and Rescue. Even if calculations can be done based on known orbital dynamics, events happen that result in missed communication windows. For example, some communication windows were not used on Mars because a rover may be still charging and therefore does not have enough energy to perform communications. Random events can also happen because of space weather. Therefore, while the window of comms can be calculated and used, the system should be able to cope with random long interruption events. Proper guards should be designed to avoid denial-of-service attacks by filling storage in the network. 4.2. Time Timers are used in transport protocols, application protocols and applications themselves for various purposes, such as detecting/ presuming packet loss or data lifetime. Timers should be therefore adjusted and configured based on the expected travel time and RTT from the source to destination. Given variations and possible dynamic changes in the network that can cause much longer latency, appropriate safeguards should be put for timer values. Lifetime is also attached to some data, such as content, security keys, certificates, tokens, session keys and naming records. Similarly, the lifetime should be adjusted and configured based on the characteristics of the applications and expected travel time and RTT. Current Internet protocols and applications typically use UTC as their time reference. There are currently work to define Lunar Standard Time, also called Coordinated Lunar Time and Mars Standard Blanchet, et al. Expires 20 December 2025 [Page 13] Internet-Draft IP in Deep Space June 2025 Time [lunartime]. Depending on the application and use case, it may be necessary to adapt the protocol or the application to use another time reference. 4.3. Signaling and Exchanges Given the large latency of space communications, multiple steps of exchanges or handshakes may still work but are far from optimal and may never converge. Therefore, applications and protocols should be adapted to minimize the number of exchanges. Similarly, applications, protocols or networking stack that depend on signaling back to the source or to somewhere in the path may arrive too late for any usefulness, because of the latency. Therefore, any signaling should be carefully designed based on the expected latency. 4.4. Bandwidth Given that space communications will always have much lower bandwidth than what is possible in shorter distances such as on Earth, optimization of the bandwidth usage is important. This can be implemented at many levels in the networking stack, starting from layer-2 to IP header compression to transport and application data compression. 4.5. Transport Since IP (and UDP) does not provide reliable transport services, such as loss, duplicates and reordered recovery, a reliable transport should be used and configured properly for space delays and intermittence for applications and protocols requiring it. Congestion control algorithms may declare congestion based on heuristics such as when delays are increasing. In that case, sources pace down to decrease their usage of the bandwidth. However, given that forwarders in space apply the store-and-forward technique when link intermittence happen, the congestion seen by the source is not actually congestion in the typical Internet sense, but deep buffer usage in forwarders, as a normal and expected operation. Therefore, congestion control should be adapted or not used because of intermittence. At least early on, while the networks are small scale, coordinated resource planning and management may be performed to avoid creating congestion. Blanchet, et al. Expires 20 December 2025 [Page 14] Internet-Draft IP in Deep Space June 2025 4.6. Addressing and Routing To minimize routing and forwarding tables, optimal address aggregation is preferred, and it starts with proper allocation of addresses. The network in deep space, not including the surface networks on celestial bodies, will grow at a small pace, which does not warrant complex routing schemes. However, over time, the network will become sufficiently complex not only because of the number of forwarders but also because of the intrinsic intermittent and delay communication patterns, which may warrant more complex routing solutions and orchestration. 4.7. Recovery on Reboot On a well-connected and low delay network such as Internet, an unexpected reboot of an intermediate node or a endpoint is recovered relatively fast: adjacency can be restored with neighbors for intermediate nodes, and endpoints can resume or restart their connections with their peers within short time. On the contrary, given the intermittence and long delays in deep space, this fast recovery is unlikely. For intermediate nodes, storing in permanent memory the contact schedule or the expected next opportunities for neighbors may help faster recovery. For endpoints, applications may keep a state context in permanent memory, either at the application layer or at the transport layer or both. 5. Security Considerations Security protocols and mitigations are most often based on time, such as keys and certificate lifetimes, tokens lifetime, firewall opened ports time windows, etc. Keys and certificates have also a lifecycle where they should be renewed. Given the delays to act, for example from Earth to a celestial body, notifications of security issues and mitigation actions will be delayed, which may increase the impact of security issues such as denial of service attacks. Blanchet, et al. Expires 20 December 2025 [Page 15] Internet-Draft IP in Deep Space June 2025 Security validation, such as certificate validation, based on on-line immediate queries to validation databases, such as done with OCSP[RFC6960], or with a certificate chain will likely take too long if the validation database is far from the validation querier. Techniques such as preemptive caching of validation chain and certs should be investigated. Certificate lifecycle should be well planned to take into account delays and intermittence, so that for example certificate renewals are done sufficiently in advance. 6. IANA Considerations There are no actions for IANA in this document. 7. References 7.1. Informative References [RFC6960] Santesson, S., Myers, M., Ankney, R., Malpani, A., Galperin, S., and C. Adams, "X.509 Internet Public Key Infrastructure Online Certificate Status Protocol - OCSP", RFC 6960, DOI 10.17487/RFC6960, June 2013, . [I-D.many-deepspace-ip-assessment] Blanchet, M., Huitema, C., and D. Bogdanović, "Revisiting the Use of the IP Protocol Stack in Deep Space: Assessment and Possible Solutions", Work in Progress, Internet-Draft, draft-many-deepspace-ip-assessment-02, 10 September 2024, . [IPoverCCSDSSpaceLinks] Consultative Committee on Space Data Systems(CCSDS), "IP OVER CCSDS SPACE LINKS, Blue Book 702", September 2012, . [SANAIPEHeaderRegistry] "Internet Protocol Extension Header", . [CCSDS_AOS] Consultative Committee on Space Data Systems(CCSDS), "AOS Space Data Link Protocol, Blue Book 732.0-B-4", October 2021, . Blanchet, et al. Expires 20 December 2025 [Page 16] Internet-Draft IP in Deep Space June 2025 [CCSDS_TM] Consultative Committee on Space Data Systems(CCSDS), "TM Space Data Link Protocol, Blue Book 132.0-B-3", October 2021, . [CCSDS_TC] Consultative Committee on Space Data Systems(CCSDS), "TC Space Data Link Protocol, Blue Book 232.0-B-4", October 2021, . [CCSDS_PROX1] Consultative Committee on Space Data Systems(CCSDS), "Proximity-1 Space Link Protocol—Data Link Layer, Blue Book 211.0-B-6", July 2020, . [CCSDS_USLP] Consultative Committee on Space Data Systems(CCSDS), "Unified Space Data Link Protocol, Blue Book 732.1-B-2", October 2021, . [CCSDS_CFDP] Consultative Committee on Space Data Systems(CCSDS), "File Delivery Protocol, Blue Book 727.0-B-5", July 2020, . [ioagmoon] Lunar Communications Architecture Working Group, Interagency Operations Advisory Group, "The Future Lunar Communications Architecture, Report of the Interagency Operations Advisory Group", January 2022, . [ioagmars] Mars and Beyond Communications Architecture Working Group, Interagency Operations Advisory Group, "The Future Mars Communications Architecture, Report of the Interagency Operations Advisory Group", February 2022, . [mro] "Mars Reconnaissance Orbiter", . [DSN] "Deep Space Network", . Blanchet, et al. Expires 20 December 2025 [Page 17] Internet-Draft IP in Deep Space June 2025 [marscommstudy] Blanchet, M., "Earth-Mars Communication Windows Usage Study", October 2024, . [idsis] "International Communication System Interoperability Standards (ICSIS)", September 2020, . [lnis] "LunaNet Interoperability Specification", September 2022, . [deepspacewikipedia] "Deep space exploration", . [maros] Gladden, R., "Mars Relay Operations Service (MaROS): A Present Service Preparing for the Future", May 2014. [tte] Wikipedia, "TTEthernet", . [lunartime] NASA, "NASA to Develop Lunar Time Standard for Exploration Initiatives", September 2024, . [imconstellation] Intuitive Machines, "Intuitive Machines Expands Data Transmission Services for Lunar and Deep Space Mission", April 2025, . Acknowledgements This following people have provided valuable feedback and comments, in no specific order: Roy Gladden, Padma Pillay-Esnault, Tomek Mrugalski. Blanchet, et al. Expires 20 December 2025 [Page 18] Internet-Draft IP in Deep Space June 2025 Authors' Addresses Marc Blanchet Viagenie Canada Email: marc.blanchet@viagenie.ca Wesley Eddy MTI Systems United States of America Email: wes@mti-systems.com Marshall Eubanks Space Initiatives Inc United States of America Email: tme@space-initiatives.com Blanchet, et al. Expires 20 December 2025 [Page 19]