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Connected Product Design & System-on-Module Strategy

2022-07-22
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Illustration: © IoT For All

Over the past two years, supply chain challenges have caused continuous headaches for design engineers. Shortages have made widely used components difficult or impossible to find. And in some cases, critical parts used in product designs have suddenly ceased production. Chip and component manufacturers are struggling with prolonged delays for materials, leading to long wait times for fulfilling customer orders. These challenges have thrown a series of wrenches into the plans of product engineers, causing major delays in their development timelines. But system-on-module (SOM) design with integrated wireless provides a way to bypass many of those challenges and accelerate development projects in the process.

'A SOM design strategy can enable engineers to bypass many of the shortages and delays that would otherwise slow or halt development timelines.' -Laird ConnectivityClick To Tweet

Advantages of SOM Design Strategy

A system-on-module design strategy can enable engineers to bypass many of the shortages and delays that would otherwise slow or halt development timelines. Companies are slashing 12-18 months off the projected timeline for projects by using a SOM that already includes wireless to simplify their connected designs in ways that reduce engineering time while also avoiding the current chip and component shortages.

Using a SOM strategy may be particularly helpful for engineering teams working on products that are not produced in ultra-high volumes like consumer products typically are. Some of the product types that SOM is often ideal for include medical devices for use in healthcare settings and in the home, industrial systems with visual displays, voice-activated handsets for commercial and industrial use cases, ruggedized scanner systems, and more healthcare, commercial and industrial use cases. Let’s take a look at several more advantages of system-on-module design:

#1: Eliminates Complex Tasks

The single-board design eliminates the complex engineering tasks that are required in the chip-down design to integrate the two key elements of a wirelessly enabled device onto a single board: the central processing unit with its associated memories and power management that supports the application and the wireless module that enables connectivity. This creates a single integrated circuit board that includes the wireless module, the device’s main processor, high-speed RAM, reliable flash memory, and power management. This allows design teams to leap ahead in the product development process. This approach also involves far fewer components, reducing the chances that projects will be bogged down by shortages and delays in the supply chain.

The integrated solution eliminates a significant amount of design work while also delivering features that would be complex to achieve with in-house engineering resources, including enhanced security, rich multimedia, enhanced connectivity, machine learning, and more. Security is one I should put a spotlight on because so many of the use cases I discussed above – including medical devices and industrial sensors – must meet stringent regulations or corporate standards for security like FIPS and secure boot. Building out these security elements can require months for a chip-down design approach because of how much of the work is time-consuming and done from scratch. It is slow, expensive, and risky. System-on-module design using pre-designed hardware and software solutions can deliver those security features out of the box, saving months of development time in the process.

#2: Resource Partitioning

Resource partitioning is another important tool to use in SOM design. Resource partitioning on the board gives designers the ability to build layers of protection and isolation within the overall design. The first form of this is the ability to run a Linux OS and RTOS simultaneously on different parts of a multi-core heterogeneous application processor. This allows the device’s most critical functions to run in real-time on the microcontroller without being interfered by user-interruptible processing priorities like touchscreen displays.

#3: Virtualization

Virtualization is typically a design concept in the world of servers and data centers where the computing resources within and between servers are used in highly flexible ways to launch, support, and upgrade applications. Virtualization in a server and data center allows organizations to direct computing resources exactly where they are needed, and the same is true within a wireless device. Virtualization within the device’s multi-core microprocessor allows different features to be fully supported by their own dedicated versions of Linux that are firewalled from one another.

For example, connectivity can be isolated to its own Linux instance while display and user input are isolated to a different Linux instance. This ensures that critical features do not have to compete against one another and are prioritized with their dedicated version of the embedded Linux OS. Another benefit of virtualization in a system-on-module system is enhanced security, allowing engineering teams to build firm walls between the wireless radio and wired networking that communicates externally and the rest of the device. This ensures that network-based attacks cannot access other critical functionality and data.

Speed & SOM

The above examples are compelling advantages of a system-on-module design strategy, particularly for applications where security is a priority. But the primary benefit is undoubtedly speed. Supply chain issues make this approach to wirelessly-enabled product design a practical necessity, and SOM design will continue to be a strategy for accelerating design projects even after supply chain challenges subside.

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  • Supply Chain and Logistics
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  • IoT Business Strategy
  • Supply Chain and Logistics
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参考译文
互联产品设计与模块系统策略
在过去两年中,供应链方面的挑战一直令设计工程师头疼不已。短缺使得广泛使用的组件很难或根本找不到。在某些情况下,用于产品设计的关键部件突然停产。芯片和组件制造商正努力应对材料的长期延误,导致客户订单的完成需要等待很长时间。这些挑战给产品工程师的计划带来了一系列的困扰,导致他们的开发时间大大延迟。但集成无线的系统对模块(SOM)设计提供了一种方法,可以绕过许多这些挑战,并加快开发项目的进程。系统-模块设计策略可以使工程师绕过许多短缺和延误,否则会减慢或暂停开发时间表。通过使用已经包含无线技术的SOM,各公司将项目的预期时间缩短了12-18个月,从而简化了连接设计,减少了工程时间,同时也避免了目前芯片和组件短缺的问题。使用SOM策略可能对工程团队特别有帮助,他们的产品不是像一般的消费产品那样以超高产量生产的。SOM最理想的一些产品类型包括用于医疗保健和家庭的医疗设备、带有视觉显示的工业系统、用于商业和工业用例的声控手持设备、坚固的扫描系统,以及更多的医疗保健、商业和工业用例。让我们来看看系统-模块设计的其他几个优点:单板设计消除了在芯片设计中将无线启用设备的两个关键元素集成到单板上所需要的复杂工程任务:支持应用程序的中央处理单元及其相关的内存和电源管理,以及启用连接的无线模块。这就形成了一个集成电路板,其中包括无线模块、设备的主处理器、高速RAM、可靠的闪存和电源管理。这允许设计团队在产品开发过程中跃进。这种方法还涉及到更少的组件,减少了项目因供应链上的短缺和延误而陷入困境的机会。集成解决方案消除了大量的设计工作,同时还交付了使用内部工程资源难以实现的功能,包括增强的安全性、丰富的多媒体、增强的连通性、机器学习等。安全性是我应该重点关注的一个问题,因为我上面讨论的许多用例(包括医疗设备和工业传感器)必须满足严格的安全性法规或企业标准,如FIPS和安全引导。构建这些安全元素可能需要几个月的芯片设计方法,因为有很多工作是耗时的,而且需要从头开始。这是缓慢的,昂贵的,有风险的。使用预先设计的硬件和软件解决方案的模块上系统设计可以开箱即用地交付这些安全特性,节省了几个月的开发时间。资源分区是SOM设计中使用的另一个重要工具。板上的资源分区使设计人员能够在整体设计中构建保护和隔离层。第一种形式是能够在多核异构应用程序处理器的不同部分上同时运行Linux OS和RTOS。这允许设备最关键的功能在微控制器上实时运行,而不受用户可中断处理优先级(如触摸屏显示)的干扰。 虚拟化通常是服务器和数据中心中的一种设计概念,服务器内部和服务器之间的计算资源以高度灵活的方式用于启动、支持和升级应用程序。服务器和数据中心中的虚拟化允许组织将计算资源精确地定向到它们需要的地方,在无线设备中也是如此。设备多核微处理器内的虚拟化允许不同的特性被各自的专用版本的Linux完全支持,这些Linux版本之间存在防火墙。例如,连接可以隔离到它自己的Linux实例,而显示和用户输入则隔离到不同的Linux实例。这确保了关键功能不需要相互竞争,并且优先于它们专用的嵌入式Linux操作系统版本。在系统-模块系统中进行虚拟化的另一个好处是增强了安全性,允许工程团队在无线无线电和有线网络之间建立坚固的墙,这些网络对外通信,并与设备的其他部分进行通信。这确保了基于网络的攻击无法访问其他关键功能和数据。上面的例子是系统-模块设计策略的显著优势,特别是对于优先考虑安全性的应用程序。但最主要的好处无疑是速度。供应链问题使得无线产品设计的这种方法成为一种实际需要,即使在供应链挑战消退后,SOM设计仍将是加速设计项目的一种策略。
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