The History of eSIM: Then, Now & in the Future

2023-03-21
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The History of eSIM: Then, Now, and In the Future
Illustration: © IoT For All

New technology developments can take time to get a foothold in the market, and eSIM has been one of many when it comes to IoT – and for several reasons. Carrier support, longevity concerns, and others have tempered the trajectory of eSIM, but analysts are estimating that eSIM is well on the rise. Let’s take a look at the history of eSIM, why eSIM was developed, the challenges this technology seeks to overcome, and where it and similar developments are evolving.

“Carrier support, longevity concerns, and others have tempered the trajectory of eSIM, but analysts are estimating that eSIM is well on the rise.”

-KORE Wireless

eSIM: Then

The SIM card has been essential to mobile communications for more than 25 years and has seen several iterations as it has shrunk in size but expanded in capabilities. The eSIM, or embedded Universal Integrated Circuit Card (eUICC), is helping mitigate some of the challenges that have risen due to traditional SIM cards, both in the consumer and the Internet of Things (IoT) sectors.

Think back to not very long ago when smartphone activation required the insertion of a SIM card. No matter the mobile operator used, the SIM card was configured to that operator’s network – making it carrier dependent. If a smartphone user wanted to switch carriers, it meant a new SIM card.

Apply that same logic to IoT, where hundreds or thousands of devices need to be configured to a network by physically inserting a SIM card. If an event or decision prompted the need for new carrier connectivity, those devices had to be removed from the field, and the old SIM cards needed to be replaced with the new carrier-specific SIM cards.

Add in the difficulty of roaming, where non-native devices could only connect to “foreign” networks for short periods, and the traditional carrier-dependent SIM card approach became a stumbling block for widespread IoT with longevity.

The Beginning of eSIM

As for the history of eSIM technology, it was originally developed by the GSMA in 2012 and started in the consumer sector with use cases in automotive, smart home devices, smartphones, tablets, and wearables. Apple most notably began widely using it in its suite of products in 2018 and 2019.

For IoT use, growth has been less explosive as the return on investment has taken more time to prove in certain use cases. It is an upfront investment, and carrier adoption was initially sluggish. However, carrier adoption has increased to a reported 200 carriers, and IoT is estimated to be the fastest-growing sector globally for eSIM adoption.

Why eSIM?

IoT is not a new segment of the technology industry and many solutions have fared well without leveraging eSIM. There are significant opportunities in eSIM:

  1. Global Connectivity: Global connectivity has always been a challenge for IoT because the carrier ecosystem is so fragmented. With the ability of eSIM to connect to different carriers, lock-in is avoided.

  2. Future-Proofed Connectivity: Many IoT solutions are deployed in the field for a device’s entire lifecycle – which can be up to 10 years in some low-complexity devices. With eSIM, there is no need to physically swap SIMs in the event of a network turndown or carrier change.

  3. Maximize ROI: With eSIM, organizations can minimize the total cost of ownership and maximize returns on IoT investments through a consolidated operational model. This is a direct change from having to manage multi-network technology across an IoT ecosystem.

  4. Carrier Agnostic: The eSIM is completely carrier agnostic, so making an MNO choice at the beginning of deployment does not have long-lasting consequences. Embedded or removable, IoT-grade and ruggedized eSIMs are remotely programmable based on GSMA eSIM specifications, with the option to integrate eSIM applets for secure authentication and network monitoring.

  5. Streamlined Logistics: Streamlining logistics and manufacturing processes is possible through eSIM. This is because the need to physically swap SIMs has been eliminated, and the eSIM is capable of hosting multiple network carriers or technologies, such as 4G and 5G.

  6. Zero-Touch Provisioning: Zero-touch provisioning is another way of saying remote provisioning or Over the Air (OTA) provisioning. This is a key function in eSIM that allows for the SIM to connect to different networks without a physical SIM swap. The ability to switch to different networks, or even network technologies, is what makes eSIM a highly attractive option for global and future-proofed IoT use cases. Not only is this beneficial to IoT solution providers, such as those leveraging IoT for business efficiency, but it is also highly useful for OEMs manufacturing IoT devices to be distributed globally.

eSIM: Now

Organizations are seeing the ROI of eSIM and skepticism about whether this technology will be widely adopted is beginning to abate. Throughout its history, use cases leveraging eSIM successfully span smart energy, drone logistics, mobile Personal Emergency Response Systems, agriculture, electric vehicle charging, and many more.

The possibilities for eSIM can be endless – with the global installed base of eSIMs estimated to be 3.4 billion by 2025. The 5G era opening up new use cases in Massive, Critical, and Ultra-Reliable IoT is an opportunity for eSIM to enable organizations access to global, perpetual connectivity.

eSIM: Future

While currently being brought to market, supporting technologies for eSIM can help make this network technology a mainstay with integral value-adds. One of those is IoT SAFE. The GSMA IoT SAFE initiative helps establish chip-to-cloud security because it begins with a SIM that is compatible with all SIM Form factors (SIM, eSIM, iSIM).

This enables security at the hardware level and helps protect IoT devices, which are often a less secure entry point into an IoT ecosystem, especially in deployments that utilize massive amounts of devices or are in hard-to-monitor areas, like bridges or underground utilities.

The SIM is used as a mini “crypto-safe” from within the device to securely establish a session with the corresponding application cloud or server. That way communications from the device to the cloud or server and back are secure.

Developments of the iSIM (integrated Subscriber Identity Module) will be the next iteration of the SIM, but not a replacement for eSIM. The eSIM is not anticipated to evolve into iSIM but simply serve as another connectivity technology choice.

A few important things to note on the iSIM – the greatest distinction will be that it is an integrated eUICC, which means chip manufacturers can design system-on-chip (SOC) infrastructure that integrates the SIM functionality.

This is not intended to be a replacement for eSIM, and it is not a soft SIM, which means software based. It will still be a hardware technology and one of the main benefits it boasts is the size and lack of space it requires in a device. As devices reduce in size, the iSIM can support that greater than other SIM form factors.

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参考译文
eSIM的历史:过去、现在和未来
新技术的发展需要一段时间才能在市场上站稳脚跟,而eSIM一直是物联网领域的众多技术之一,这有几个原因。运营商的支持、对使用寿命的担忧等因素削弱了eSIM的发展轨迹,但分析师们估计eSIM仍在稳步增长。让我们来看看eSIM的历史,为什么要开发eSIM,这项技术要克服的挑战,以及它和类似的发展在哪里发展。“运营商的支持、使用寿命的担忧等因素削弱了eSIM的发展轨迹,但分析师们估计,eSIM仍在稳步增长。”在过去的25年里,SIM卡一直是移动通信的核心,随着它的尺寸缩小但功能扩展,它经历了几次迭代。eSIM,或嵌入式通用集成电路卡(eUICC),正在帮助缓解传统SIM卡在消费者和物联网(IoT)领域所带来的一些挑战。回想一下不久前,激活智能手机还需要插入SIM卡。无论使用哪个移动运营商,SIM卡都是根据该运营商的网络配置的,这使得它依赖于运营商。如果智能手机用户想换运营商,就意味着要换一张新的SIM卡。将同样的逻辑应用于物联网,需要通过物理插入SIM卡将数百或数千个设备配置到网络中。如果某个事件或决定需要新的运营商连接,那么这些设备必须从现场移除,旧的SIM卡需要替换为新的运营商专用SIM卡。再加上漫游的困难,非本地设备只能在短时间内连接到“国外”网络,传统的依赖运营商的SIM卡方法成为了广泛使用物联网的绊脚石。至于eSIM技术的历史,它最初是由GSMA在2012年开发的,从消费领域开始,用例包括汽车、智能家居设备、智能手机、平板电脑和可穿戴设备。最值得注意的是,苹果公司在2018年和2019年开始在其系列产品中广泛使用它。对于物联网的使用,增长不那么爆炸性,因为在某些用例中,投资回报需要更多的时间来证明。这是一项前期投资,而且运营商的使用率最初很低。然而,据报道,运营商的采用已经增加到200家,物联网估计是全球eSIM采用增长最快的领域。物联网并不是技术行业的一个新领域,许多解决方案在没有利用eSIM的情况下发展得很好。eSIM有很大的机会:组织正在看到eSIM的投资回报率,对这项技术是否会被广泛采用的怀疑正在开始减弱。纵观eSIM的历史,利用eSIM的用例成功跨越了智能能源、无人机物流、移动个人应急响应系统、农业、电动汽车充电等等。eSIM的可能性是无限的——到2025年,全球eSIM的安装基数估计将达到34亿。5G时代在大规模、关键和超可靠的物联网领域开辟了新的用例,这为eSIM提供了一个机会,使组织能够访问全球永久连接。目前,eSIM的支持技术正在推向市场,有助于使这种网络技术成为具有整体附加值的主流。其中之一就是物联网安全。GSMA IoT SAFE计划有助于建立芯片到云的安全性,因为它始于与所有SIM卡形式因素(SIM、eSIM、iSIM)兼容的SIM卡。这实现了硬件层面的安全性,并有助于保护物联网设备,这些设备通常是物联网生态系统中不太安全的入口点,特别是在使用大量设备或在难以监控的区域(如桥梁或地下公用设施)的部署中。 SIM卡在设备内部用作迷你“加密安全”,以安全地与相应的应用程序云或服务器建立会话。这样,设备与云或服务器之间的通信是安全的。iSIM(集成用户识别模块)的开发将是SIM的下一个迭代,但不是eSIM的替代品。预计eSIM不会演变成iSIM,而只是作为另一种连接技术的选择。关于iSIM需要注意的一些重要事项-最大的区别将是它是一个集成的eUICC,这意味着芯片制造商可以设计集成SIM功能的片上系统(SOC)基础设施。这并不是eSIM的替代品,它也不是软SIM,软SIM指的是基于软件的SIM。它仍将是一种硬件技术,它所吹嘘的主要好处之一是它在设备中所需的尺寸和空间不足。随着设备尺寸的减小,iSIM可以支持比其他SIM更大的尺寸。
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