To say that the future of the U.S. military is more software-enabled, and more network-enabled than ever before would be a massive understatement. Everything that the military is developing and piloting for use in battle today needs connectivity.

Just look at the Army’s IVAS program, which is working to deliver an advanced augmented reality (AR) solution to the warfighter on the battlefield – putting important information, situational awareness capabilities, and other tools directly in their field of vision via a HoloLens headset.

According to Steve Kitay, the Senior Director of Azure Space at Microsoft, the IVAS headset will be augmented by Azure cloud services, and function to, “[keep] soldiers safer and [make] them more effective…[by] delivering enhanced situational awareness, enabling information sharing, and decision making for a variety of scenarios.”

And while this is certainly an exciting and revolutionary new tool in the warfighter’s kit, it’s only possible with connectivity in theater.

If everything that the warfighter relies on in theater is going to become network-enabled, then connectivity needs to be assured. Training a soldier to rely on a tool that only works when connected would be setting them up for failure if the network that supports the tool can be degraded or denied. Resilient, assured networks are no longer “nice to have,” they’re mission-critical.

While that looks good on paper, assured networks are easier to discuss – or write about – than they are to implement in the real world.

Complexity and a lack of transparency impact uptime
The terrestrial networks that provide the backbone of our high-bandwidth connectivity at home are incredibly stable and reliable, with SLAs and uptimes that ensure that connectivity is almost always available. Unfortunately, those terrestrial networks, themselves, are often unavailable where the military and government operates.

In foreign countries and isolated geographic locations, terrestrial networks may not exist at all. If that infrastructure does exist, it could be unreliable, or it could be untrusted. But that’s not just a problem that the military faces abroad. There are large swaths of our own country with no high-bandwidth terrestrial networks due to cost, geography, or other reasons.

In these places, satellite connectivity is essential and necessary to deliver the high-bandwidth, high-throughput, low-latency connectivity necessary for the government and military to operate their next-generation, network-enabled platforms, devices, and vehicles.

“…Hydra includes an inventory management system that integrates shared and dedicated devices, circuits, and the space segment into the same contextual environment…[allowing users] to schedule and monitor the entire end-to-end network in a single, integrated pane of glass, diagnose problems more rapidly, and fix problems before they take applications, services, and capabilities offline.” – Amit Katti

But adding satellite communications to the network infrastructure for government agencies and the military effectively increases the complexity of the networks – giving them a network architecture that incorporates assets on Earth, and in space. Much like with a modern car that’s more of a computer than an automobile, this increased complexity can also mean that there are more things that can fail or more things that can go wrong.

Worse, the military is utilizing a number of disparate terrestrial networks, disparate terrestrial hardware, and utilizing space assets and networks that include their own military assets, as well as commercial assets. This creates a lack of transparency and visibility into everything that’s happening across the network – a problem that the military is actively working to fix by embracing a joint operating environment across all of the DoD’s branches and organizations.

For the government and military to ensure connectivity and have assured networks, they need the ability to see the entire network – both terrestrial assets and space assets – on a single pane of glass. If a single, unified view of the network and the individual devices connected to it were available, the government and military would be able to diagnose problems more rapidly, and fix problems before they take applications, services, and capabilities offline.

Luckily, such a solution now exists.

Increasing transparency and uptime with Hydra
Earlier this week, commercial satellite operator, SES Space and Defense launched a new common operational picture (COP) platform called Hydra that the company claims, “…provides end-to-end situational awareness in a single unified operational network platform.”

Hydra was built in-house by SES Space and Defense specifically for their government and military customers. The solution integrates network data from multiple different sources – including operational data from the company’s satellite networks – and enables users to display it on a single dashboard or pane of glass. This could effectively enable the government and military the opportunity to view everything happening on and within their networks in one place – increasing transparency and allowing them to identify and remediate problems with the network more quickly.

“In addition to providing basic M&C data, Hydra includes an inventory management system that integrates shared and dedicated devices, circuits, and the space segment into the same contextual environment,“ explained Amit Katti, a Principal Engineer at SES Space and Defense. “This ability to incorporate and visualize the entire network allows the customer to schedule and monitor the entire end-to-end network in a single, integrated pane of glass, diagnose problems more rapidly, and fix problems before they take applications, services, and capabilities offline.”

COP platforms, such as Hydra, could be revolutionary in enabling the military to better monitor their networks – both on Earth and in space – and identify problems before they bring down networks. With network-enabled and software-enabled devices, applications, and platforms making their way into every government and military mission and operation, the timing couldn’t be better.

Networks aren’t “nice to have” at the tactical edge anymore. They’re essential. COP platforms like Hydra are ensuring that these networks are always on and available to the warfighter. This way, the next-generation, high-tech tools that our government and military personnel rely on are there when and where they need them – even in the most remote and austere of environments.

In our next article on the Government Satellite Report, we’ll look at the military’s push for an integrated commercial and military satellite architecture, and how COP platforms like Hydra could help make that a reality.

To learn more about the new Hydra common operational picture platform, click HERE.

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Understanding that cloud customers will rely on satellite to access their cloud services and cloud-native applications in geographically remote and isolated areas, Microsoft recently launched Azure Space, and announced a number of innovative partnerships with satellite providers, such as SES Space and Defense. They also introduced Azure Orbital and the Azure Modular Data Center, which are designed to help make cloud connectivity at the tactical edge easier for government cloud users.

In the second part of our illuminating interview with Steve, we set out to learn more about these exciting announcements from Azure Space. We also discussed how innovations in the space and satellite industry are opening the door for the ubiquitous, global connectivity necessary to power government cloud and digital transformation initiatives.

Government Satellite Report (GSR): While our readers are undoubtedly familiar with Microsoft Azure, they may not be as familiar with Azure Space, which I understand is a relatively new entity. Can you tell our readers a bit more about Azure Space and its mission?

Steve Kitay: Microsoft publicly launched Azure Space a year ago, although we’ve been working on standing it up for more than two years. The mission of Azure Space is bringing the cloud and space together to empower our customers both on and off the planet.

Our approach to Azure Space is through partnerships and enabling an ecosystem. Microsoft isn’t building and launching its own satellites, but rather partnering with others that do to provide connectivity solutions both to space systems, and anywhere on earth.

We also have cutting-edge AI and machine learning (ML) algorithms to drive insights from the data coming from space. We are also supporting the developer community with unique simulation and digital engineering capabilities. And lastly, while we’re not building or launching our own satellites, we’re bringing our innovation into space.

For example, HP has a computer on the ISS called the Spaceborne computer that we’ve connected to the hyperscale cloud to enable researchers and astronauts to do more. There are a variety of innovation areas that we’re exploring and working on both on and off the planet.

GSR: What is Microsoft Azure Orbital? What does it enable government cloud users to do?

Steve Kitay: Azure Orbital is a fully managed, cloud-based ground station as a service that allows users to communicate with their satellite constellation. This allows them to download data, uplink commands, and process data in the cloud. It also enables Azure services to be deployed to generate products for their customers.

“Governments worldwide are looking for these kinds of connectivity solutions to meet their needs. What we’re doing with SES is bringing the connectivity and compute together so that they’re not just moving the data, but they’re deriving insights and understanding from that data.” – Steve Kitay

Ultimately, it provides modern ground segment technologies, allowing satellite operators to focus on their space mission and product, offloading the responsibility of deployment and maintenance of ground station assets.

The system that we’ve built out is on top of Azure’s global infrastructure and low-latency global fiber networks. The capability of Azure Orbital is building upon a partner ecosystem that includes KSAT, ViaSat, Kratos, Emergent Space Technologies, and several others.

GSR: What about the Microsoft Modular Data Center (MDC)? What is the MDC and what does it do? How is it different from other data centers? What can it enable for government cloud users?

Steve Kitay: We have a suite of edge capabilities, and the MDC is one of them. The MDC and our other edge devices enable the use of Azure from anywhere in the world.

MDC gives customers the capability to deploy a modular data center to remote locations, or to augment existing infrastructure. A major differentiator for the MDC is that customers can run the unit with full network connectivity, or in situations where it’s occasionally connected or even fully disconnected.

“Microsoft isn’t building and launching its own satellites, but rather partnering with others that do to provide connectivity solutions both to space systems, and anywhere on earth.” – Steve Kitay

We have also built in an ability to have satellite connectivity with SES, and other providers, to enable the data center to be connected back to the hyperscale cloud.

GSR: In a recent press release, it was announced that Microsoft would leverage the SES multi-orbit satellite system to give government entities to cloud resources practically anywhere on the globe. Why is a multi-orbit satellite solution ideal for this? What advantages does a multi-orbit constellation or service have over one that is in a single, dedicated orbit?

Steve Kitay: SES is a close partner of Microsoft, and their multi-orbit satellite constellation allows us to better service our customers.

By enabling our customers to access different satellite services at different orbits, we’re giving them the choice and flexibility to choose the right satellite service for their needs and requirements.

Satellite services from different orbits have different advantages, and different satellite services may be optimal for a particular customer’s needs and requirements. By enabling access to multiple options, Microsoft ensures that they have different options they need to meet their needs in regard to pricing, bandwidth, capacity, latency and other factors.

“Azure Orbital is a fully managed, cloud-based ground station as a service that allows users to communicate with their satellite constellation. This allows them to download data, uplink commands, and process data in the cloud.” – Steve Kitay

Our approach brings together partnerships and products to create a comprehensive and resilient satellite tool and solutions that meet the needs of our customers.

GSR: SES is on the precipice of launching a new satellite service – SES O3b mPOWER. What will this new service mean for government and military cloud users? How can it change what is currently possible at the tactical edge?

Steve Kitay: O3b mPOWER is a satellite constellation that we’re specifically partnering with and that they’re leveraging Azure Orbital for ground infrastructure. It’s a Medium Earth Orbit (MEO) satellite service that delivers a tremendous increase in flexibility and throughput speed, and cloud-scale capacity to Azure locations across the Earth. And, ultimately, what that means for customers is that fiber-equivalent connectivity will now be available wherever users are located – including in the air, at sea, or on the ground in remote sites in geographically-isolated regions.

O3b mPOWER is delivering secure and resilient network architecture for robust connectivity whether the mission is establishing a secure network at a tactical edge or deploying a UAV for live HD video along a border. Governments worldwide are looking for these kinds of connectivity solutions to meet their needs. What we’re doing with SES is bringing the connectivity and compute together so that they’re not just moving the data, but they’re deriving insights and understanding from that data.

For additional information about how Ob3 mPOWER can enable next-generation technologies on the battlefield, click HERE to download a complimentary copy of the whitepaper, “High Throughput Satellites for U.S. Government Applications.”

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This digital transformation was arguably kickstarted by the widespread adoption of the cloud and cloud resources across the government. And it’s being driven forward by cloud-native applications that are being developed, deployed, and hosted in the cloud, where they can be accessed by government and military personnel whenever and wherever the mission requires.

While this digital transformation will only result in the government becoming more effective and efficient, it can only succeed if connectivity and access to cloud resources are ubiquitous across the globe.

The connectivity required for government and military organizations to access and utilize cloud services at the tactical edge is most effectively delivered by satellite. This is creating new collaborations and partnerships between those that operate satellite networks, and the organizations that provide cutting-edge cloud services.

One of the cloud providers leading the pack in embracing satellite connectivity is Microsoft Azure, which recently launched Azure Space, and announced a number of innovative partnerships with satellite providers, such as SES Space and Defense.

We recently sat down with Steve Kitay, the Senior Director of Azure Space at Microsoft, to discuss the trends driving the need for satellite and cloud partnerships, and how cloud services delivered via satellite could revolutionize how governments operate.

Government Satellite Report (GSR): Transitioning to the cloud has been a major initiative for the government over the course of the last few years. What types of cloud use cases are we seeing in the government? What different types of applications and workloads are being moved to the cloud by government agencies? Are mission-critical workloads making their way into the cloud?

Steve Kitay: Government agencies want to benefit from commercial cloud innovation. They want to take advantage of its speed, its scale, and its agility. Transitioning to the cloud reduces costs, provides access to the latest technologies, and diminishes the burden of having to maintain their own legacy infrastructure.

We see government agencies moving a range of workloads to the cloud to rapidly grow their mission capabilities. At the start of the COVID pandemic, we saw a rapid shift to cloud services to enable secure remote work environments through Azure Commercial and Government Clouds, and through the Office 365 productivity suites.

We’re seeing this shift to the cloud across a range of agencies. We’re working with a number of agencies, in particular, to help them use the cloud to solve their mission problems. The Department of Agriculture has leveraged a project called Farm Beats that accesses Azure’s repositories of analytics tools to understand data, and uses AI to help farmers cut costs, increase yields and sustainably grow crops that are more resilient to threats like climate change.

“When we bring (IoT and hybrid infrastructure) together, with AI running across these systems, we enter into an era of Intelligent Edge – a continually expanding set of connected systems and devices that gather and analyze information close to the physical world where the data resides and is harvested.” – Steve Kitay

The Department of Defense (DoD) is working on building out its enterprise cloud capabilities. Branches within the DoD, such as the Air Force, have deployed their own instances. Air Force Cloud One is a good example of a military branch using the cloud to provide foundational cloud capabilities, including networking, monitoring, access control, and identity management.

GSR: Are we seeing the need across different levels and organizations within the government for access to cloud solutions in the field, off-grid, and at the tactical edge? What is driving this requirement? What types of capabilities and applications are they looking to access?

Steve Kitay: The U.S. Government has been clear that they are trying to tap into commercial innovation to unlock new mission scenarios that were simply not possible before. There are two trends that we’re seeing in the government that really illustrate that.

The first trend is the Internet of Things (IoT), which utilizes smart sensors, connected devices, and other network-enabled endpoints to change the way that agencies approach problems. From equipment maintenance, to measuring air quality, to smart cities, and even military outposts, they’re implementing devices that are cloud-connected by default.

The other trend is movement towards hybrid infrastructure – or the integration of traditional datacenter infrastructure, edge devices, and the public cloud. This gives the government access to more compute capabilities in even the world’s most remote locations.

When we bring these two technology trends together, with AI running across these systems, we enter into an era of Intelligent Edge – a continually expanding set of connected systems and devices that gather and analyze information close to the physical world where the data resides and is harvested. This enables them to get real-time insights and immersive experiences that are highly responsive and contextually aware.

There is a space program that is a great example of the Intelligent Edge called the Casino Program, which was done with the Defense Innovation Unit in support of the U.S. Space Force. The rising number of satellites proliferating in low earth orbit (LEO) presents a new data challenge for the ground segment of missions—a segment that is often overlooked.

The Casino Program Office demonstrated fast, flexible, and extensible cloud commercial capabilities for ground processing in support of defense missions.  In this project, the joint Ball Aerospace and Microsoft team demonstrated the ability to transmit overhead, persistent infrared data through commercial satellites to the ground and then be processed both in the hyperscale Azure data center, as well as directly to a tactical vehicle in the field that was equipped with an Azure stack edge device.

“The need for bandwidth and cloud services in remote locations is a large and growing global challenge. The alignment and integration of the Azure cloud with satellites and terrestrial networks further enables the connected, Intelligent Edge…” – Steve Kitay

In this scenario, the overhead satellites transmitted the images of the environment, and that data was then pushed to both Azure and the Azure stack edge device where machine learning algorithms processed the images and detected certain activities and features. This machine learning identification generated insights which were converted into messages and disseminated to multiple endpoints.

This project represents a huge leap forward in reducing the time to actionable insight—if users are on the ground in a tactical edge vehicle or located at a command center, users can obtain necessary information accurately, quickly, and securely.

GSR: How else could access to cloud resources at the tactical edge or on the battlefield impact our warfighters? What could it enable them to do? What services/capabilities could it make possible for them?

Steve Kitay: Well, another great example is the Army’s IVAS program, which is bringing state-of-the-art cloud and mixed reality capability to soldiers at the tactical edge.

The IVAS headset, which is based on HoloLens and augmented by Azure cloud services, delivers a platform that keeps soldiers safer and makes them more effective. The program delivers enhanced situational awareness, enabling information sharing, and decision making for a variety of scenarios.

GSR: Microsoft has been working with satellite providers – including SES – to enable remote, off-grid access to cloud resources. Why is satellite the right choice for this?

Steve Kitay: Satellite is the right choice because space provides is a global perspective. It enables us to connect people anywhere, whether they’re in the middle of the ocean, the desert, or anywhere else on the Earth.

What is changing now with satellite communications is the type of services being offered. New services are now available with higher bandwidth and lower latencies. And space-generated data is growing exponentially, which requires expanded ground control capabilities, as well as data processing, storage, and analytics to turn that data into knowledge and actionable insights.

The need for bandwidth and cloud services in remote locations is a large and growing global challenge. The alignment and integration of the Azure cloud with satellites and terrestrial networks further enables the connected, Intelligent Edge that I referenced earlier.

For additional information about how Ob3 mPOWER can enable next-generation technologies on the battlefield, click HERE to download a complimentary copy of the whitepaper, “High Throughput Satellites for U.S. Government Applications.”

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