T-Mobile has launched the first Standalone 5G service in America to give you a great network experience. To access Standalone 5G, the SIM card in your compatible 5G device must be Standalone 5G capable.

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A communication device is a hardware device capable of transmitting an analog or digital signal over the telephone, other communication wire, or wirelessly. A classic example of a communication device is a computer modem, which converts a computer's digital information to an analog signal for transmission over a telephone line. Here's how to reset settings if your iPhone can't connect to data or send / receive messages. Deploy an automated tool on network perimeters that monitors for unauthorized transfer of sensitive information and blocks such transfers while alerting information security professionals. If USB storage devices are required, enterprise software should be used that can configure systems to allow the use of specific devices.

LoRaWAN ® network architecture is deployed in a star-of-stars topology in which gateways relay messages between end-devices and a central network server. The gateways are connected to the network server via standard IP connections and act as a transparent bridge, simply converting RF packets to IP packets and vice versa. All other UC P4 (formerly UCB PL2) security controls, including the protected subnet requirement, do still apply to covered devices residing on the Earl Warren Hall data center network. UC P2/P3 (formerly UCB PL1) data is not required to meet MSSEI encryption in transit requirements when traversing the UC Berkeley campus wired network.

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Why did I get a message about changing my SIM card?

• T-Mobile is committed to providing the largest, most reliable 5G network in the Nation. This means we are regularly rolling out new technology to enhance and grow our 5G network.
• While your current SIM card is 5G compatible, it is not capable of using the 5G standalone technology we recently rolled out.
• Changing your SIM card will help to ensure you get more 5G in more places when using a compatible device, such as indoors and in rural locations, and will make sure you're ready to take advantage of future network enhancement.

What to do

• If you have the SIM card that came with your 5G device, you just need to activate it.
• If you no longer have the SIM that came with your 5G device, contact us or stop by a store for a replacement SIM.
  For your security, the account holder or an authorized user must make the request.

What is Standalone 5G?

What it does

Standalone architecture is the future of wireless connectivity. It will help bring 5G closer to reaching its true potential with:

• Faster speeds
• Lower latency, so you can experience shorter delays
• Massive connectivity

Why it matters

Standalone 5G will help pave the way for new applications and supercharge things like:

• Mobile augmented and virtual reality
• Cloud gaming
• Real-time translation
• And so much more!

What you need to access Standalone 5G

At T-Mobile, there is no extra cost for Standalone 5G. Here’s all you need to get it (see FAQs for more details):

• A T-Mobile 5G compatible device that has received a software update to be compatible with Standalone 5G
• Be in a location with Standalone 5G coverage

FAQs

T-Mobile recently launched new 5G standalone technology which will enable our customers to get more 5G in more places when using a compatible SIM and device. The SIM card you are using is not compatible with this new 5G standalone technology. You’ll want to update your SIM to ensure you can get the best network experience.

Changing your SIM will help to ensure you can access both our Standalone and Non-Standalone 5G when using a compatible device. While you may not see an immediate difference, this will ensure that you benefit from ongoing enhancements we will be making to our 5G network over the years.

Non-standalone (NSA) relies on a mid-band LTE signal to access the 5G network. The device must connect to both LTE AND 5G. Standalone (SA) operates independently of the LTE network. With SA, the device connects to LTE OR 5G, whatever is the appropriate core network. SA allows full access to the benefits of 5G without the limitations of legacy LTE.

Customers’ T-Mobile and Metro by T-Mobile plans include access to 5G (SA and NSA) at no extra cost.

Yes, your device must receive a software update from the manufacturer to work on 5G SA. All 5G capable devices will eventually be sent the software update; for some devices this has already happened while others will come at a later date. T-Mobile doesn’t currently have information from the manufacturers to know when.

If your devices haven’t received the update yet, it will still work great on our LTE network and on the Non-Standalone (NSA) 5G coverage, so you will see 5G when you travel to other locations. Once the software update is available, you’ll pick up the new 5G technology at your location too!

SA is a major milestone as it’s essential to unlocking truly transformational 5G in the future. Currently, Standalone 5G allows T-Mobile to expand 5G coverage and performs similar to NSA that already exists today. Down the road, Standalone 5G is expected to deliver the capacity, data speeds, and lower latency that will fuel future innovation. As 5G apps and innovations are introduced, they will be optimized on Standalone 5G technology.

Currently, Standalone 5G performs similar to NSA that already exists today. Down the road, Standalone 5G is expected to deliver the capacity, data speeds, and lower latency that will fuel future innovation. As 5G apps and innovations are introduced, they will be optimized on Standalone 5G technology.

No, the majority of our nationwide 5G network is on NSA. We have started lighting up Standalone 5G in select areas and will roll out additional SA as we continue to expand the T-Mobile 5G network.

We’ve just started rolling out SA so it’s only available in select areas. The coverage map shows our nationwide 5G footprint so you’ll notice the expanded 5G coverage, especially in some rural areas and indoor locations where there wasn’t 5G coverage before. The map does not, however, distinguish SA from NSA. A T-Mobile care or retail sales associate can help identify if there’s SA in your area – if you’d like to learn more, please visit a T-Mobile retail store or call 611 on your mobile device.

Sprint 5G devices cannot access our newest Standalone 5G technology. These devices can, however, access our Nationwide 5G (NSA) coverage.

Yes, customers on Metro by T-Mobile who meet the technical requirements can access Standalone 5G.

Capable device required; coverage not available in some areas. While 5G access won't require a certain plan or feature, some uses/services might. See Coverage details, Terms and Conditions, and Open Internet information for network management details (like video optimization) at T-Mobile.com.

The LoRaWAN^® specification is a Low Power, Wide Area (LPWA) networking protocol designed to wirelessly connect battery operated ‘things’ to the internet in regional, national or global networks, and targets key Internet of Things (IoT) requirements such as bi-directional communication, end-to-end security, mobility and localization services.

LoRaWAN^® network architecture is deployed in a star-of-stars topology in which gateways relay messages between end-devices and a central network server. The gateways are connected to the network server via standard IP connections and act as a transparent bridge, simply converting RF packets to IP packets and vice versa. The wireless communication takes advantage of the Long Range characteristics of the LoRaÒ physical layer, allowing a single-hop link between the end-device and one or many gateways. All modes are capable of bi-directional communication, and there is support for multicast addressing groups to make efficient use of spectrum during tasks such as Firmware Over-The-Air (FOTA) upgrades or other mass distribution messages.

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LoRaWAN has three different classes of end-point devices to address the different needs reflected in the wide range of applications:

Class A – Lowest power, bi-directional end-devices:

The default class which must be supported by all LoRaWAN end-devices, class A communication is always initiated by the end-device and is fully asynchronous. Each uplink transmission can be sent at any time and is followed by two short downlink windows, giving the opportunity for bi-directional communication, or network control commands if needed. This is an ALOHA type of protocol.
The end-device is able to enter low-power sleep mode for as long as defined by its own application: there is no network requirement for periodic wake-ups. This makes class A the lowest power operating mode, while still allowing uplink communication at any time.
Because downlink communication must always follow an uplink transmission with a schedule defined by the end-device application, downlink communication must be buffered at the network server until the next uplink event.

Class B – Bi-directional end-devices with deterministic downlink latency:

In addition to the class A initiated receive windows, class B devices are synchronised to the network using periodic beacons, and open downlink ‘ping slots’ at scheduled times. This provides the network the ability to send downlink communications with a deterministic latency, but at the expense of some additional power consumption in the end-device. The latency is programmable up to 128 seconds to suit different applications, and the additional power consumption is low enough to still be valid for battery powered applications.

Class C – Lowest latency, bi-directional end-devices:

In addition to the class A structure of uplink followed by two downlink windows, class C further reduces latency on the downlink by keeping the receiver of the end-device open at all times that the device is not transmitting (half duplex). Based on this, the network server can initiate a downlink transmission at any time on the assumption that the end-device receiver is open, so no latency. The compromise is the power drain of the receiver (up to ~50mW) and so class C is suitable for applications where continuous power is available.
For battery powered devices, temporary mode switching between classes A & C is possible, and is useful for intermittent tasks such as firmware over-the-air updates.

In addition to frequency hopping, all communication packets between end-devices and gateways also include a variable ‘Data rate’ (DR) setting. The selection of the DR allows a dynamic trade-off between communication range and message duration. Also, due to the spread spectrum technology, communications with different DRs do not interfere with each other and create a set of virtual ‘code’ channels increasing the capacity of the gateway. To maximize both battery life of the end-devices and overall network capacity, the LoRaWAN^® network server manages the DR setting and RF output power for each end-device individually by means of an Adaptive Data Rate (ADR) scheme.

LoRaWAN^® baud rates range from 0.3 kbps to 50 kbps.

Security is a primary concern for any mass IoT deployment and the LoRaWAN^® specification defines two layers of cryptography:

• A unique 128-bit Network Session Key shared between the end-device and network server
• A unique 128-bit Application Session Key (AppSKey) shared end-to-end at the application level

AES algorithms are used to provide authentication and integrity of packets to the network server and end-to-end encryption to the application server. By providing these two levels, it becomes possible to implement ‘multi-tenant’ shared networks without the network operator having visibility of the users payload data.

The keys can be Activated By Personalisation (ABP) on the production line or during commissioning, or can be Over-The-Air Activated (OTAA) in the field. OTAA allows devices to be re-keyed if necessary.

Read our Security Whitepaper here

Read our Security FAQs here /resource-hub/lorawan-security-faq

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The specification defines the device-to-infrastructure (LoRa®) physical layer parameters & (LoRaWAN^®) protocol and so provides seamless interoperability between manufacturers, as demonstrated via the device certification program.
While the specification defines the technical implementation, it does not define any commercial model or type of deployment (public, shared, private, enterprise) and so offers the industry the freedom to innovate and differentiate how it is used.
The LoRaWAN^® specification is developed and maintained by the LoRa Alliance^®: an open association of collaborating members.

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