New approaches for embedded development

The idea for this posting started when I read New approaches to dominate in embedded development article. Then I found some ther related articles and here is the result: long article.

Embedded devices, or embedded systems, are specialized computer systems that constitute components of larger electromechanical systems with which they interface. The advent of low-cost wireless connectivity is altering many things in embedded development: With a connection to the Internet, an embedded device can gain access to essentially unlimited processing power and memory in cloud service – and at the same time you need to worry about communication issues like breaks connections, latency and security issues.

Those issues are espcecially in the center of the development of popular Internet of Things device and adding connectivity to existing embedded systems. All this means that the whole nature of the embedded development effort is going to change. A new generation of programmers are already making more and more embedded systems. Rather than living and breathing C/C++, the new generation prefers more high-level, abstract languages (like Java, Python, JavaScript etc.). Instead of trying to craft each design to optimize for cost, code size, and performance, the new generation wants to create application code that is separate from an underlying platform that handles all the routine details. Memory is cheap, so code size is only a minor issue in many applications.

Historically, a typical embedded system has been designed as a control-dominated system using only a state-oriented model, such as FSMs. However, the trend in embedded systems design in recent years has been towards highly distributed architectures with support for concurrency, data and control flow, and scalable distributed computations. For example computer networks, modern industrial control systems, electronics in modern car,Internet of Things system fall to this category. This implies that a different approach is necessary.

Companies are also marketing to embedded developers in new ways. Ultra-low cost development boards to woo makers, hobbyists, students, and entrepreneurs on a shoestring budget to a processor architecture for prototyping and experimentation have already become common.If you look under the hood of any connected embedded consumer or mobile device, in addition to the OS you will find a variety of middleware applications. As hardware becomes powerful and cheap enough that the inefficiencies of platform-based products become moot. Leaders with Embedded systems development lifecycle management solutions speak out on new approaches available today in developing advanced products and systems.

Traditional approaches

C/C++

Tradionally embedded developers have been living and breathing C/C++. For a variety of reasons, the vast majority of embedded toolchains are designed to support C as the primary language. If you want to write embedded software for more than just a few hobbyist platforms, your going to need to learn C. Very many embedded systems operating systems, including Linux Kernel, are written using C language. C can be translated very easily and literally to assembly, which allows programmers to do low level things without the restrictions of assembly. When you need to optimize for cost, code size, and performance the typical choice of language is C. Still C is today used for maximum efficiency instead of C++.

C++ is very much alike C, with more features, and lots of good stuff, while not having many drawbacks, except fror it complexity. The had been for years suspicion C++ is somehow unsuitable for use in small embedded systems. At some time many 8- and 16-bit processors were lacking a C++ compiler, that may be a concern, but there are now 32-bit microcontrollers available for under a dollar supported by mature C++ compilers.Today C++ is used a lot more in embedded systems. There are many factors that may contribute to this, including more powerful processors, more challenging applications, and more familiarity with object-oriented languages.

And if you use suitable C++ subset for coding, you can make applications that work even on quite tiny processors, let the Arduino system be an example of that: You’re writing in C/C++, using a library of functions with a fairly consistent API. There is no “Arduino language” and your “.ino” files are three lines away from being standard C++.

Today C++ has not displaced C. Both of the languages are widely used, sometimes even within one system – for example in embedded Linux system that runs C++ application. When you write a C or C++ programs for modern Embedded Linux you typically use GCC compiler toolchain to do compilation and make file to manage compilation process.

Most organization put considerable focus on software quality, but software security is different. When the security is very much talked about topic todays embedded systems, the security of the programs written using C/C++ becomes sometimes a debated subject. Embedded development presents the challenge of coding in a language that’s inherently insecure; and quality assurance does little to ensure security. The truth is that majority of today’s Internet connected systems have their networking fuctionality written using C even of the actual application layer is written using some other methods.

Java

Java is a general-purpose computer programming language that is concurrent, class-based and object-oriented.The language derives much of its syntax from C and C++, but it has fewer low-level facilities than either of them. Java is intended to let application developers “write once, run anywhere” (WORA), meaning that compiled Java code can run on all platforms that support Java without the need for recompilation.Java applications are typically compiled to bytecode that can run on any Java virtual machine (JVM) regardless of computer architecture. Java is one of the most popular programming languages in use, particularly for client-server web applications. In addition to those it is widely used in mobile phones (Java apps in feature phones,) and some embedded applications. Some common examples include SIM cards, VOIP phones, Blu-ray Disc players, televisions, utility meters, healthcare gateways, industrial controls, and countless other devices.

Some experts point out that Java is still a viable option for IoT programming. Think of the industrial Internet as the merger of embedded software development and the enterprise. In that area, Java has a number of key advantages: first is skills – there are lots of Java developers out there, and that is an important factor when selecting technology. Second is maturity and stability – when you have devices which are going to be remotely managed and provisioned for a decade, Java’s stability and care about backwards compatibility become very important. Third is the scale of the Java ecosystem – thousands of companies already base their business on Java, ranging from Gemalto using JavaCard on their SIM cards to the largest of the enterprise software vendors.

Although in the past some differences existed between embedded Java and traditional PC based Java solutions, the only difference now is that embedded Java code in these embedded systems is mainly contained in constrained memory, such as flash memory. A complete convergence has taken place since 2010, and now Java software components running on large systems can run directly with no recompilation at all on design-to-cost mass-production devices (consumers, industrial, white goods, healthcare, metering, smart markets in general,…) Java for embedded devices (Java Embedded) is generally integrated by the device manufacturers. It is NOT available for download or installation by consumers. Originally Java was tightly controlled by Sun (now Oracle), but in 2007 Sun relicensed most of its Java technologies under the GNU General Public License. Others have also developed alternative implementations of these Sun technologies, such as the GNU Compiler for Java (bytecode compiler), GNU Classpath (standard libraries), and IcedTea-Web (browser plugin for applets).

My feelings with Java is that if your embedded systems platform supports Java and you know hot to code Java, then it could be a good tool. If your platform does not have ready Java support, adding it could be quite a bit of work.

 

Increasing trends

Databases

Embedded databases are coming more and more to the embedded devices. If you look under the hood of any connected embedded consumer or mobile device, in addition to the OS you will find a variety of middleware applications. One of the most important and most ubiquitous of these is the embedded database. An embedded database system is a database management system (DBMS) which is tightly integrated with an application software that requires access to stored data, such that the database system is “hidden” from the application’s end-user and requires little or no ongoing maintenance.

There are many possible databases. First choice is what kind of database you need. The main choices are SQL databases and simpler key-storage databases (also called NoSQL).

SQLite is the Database chosen by virtually all mobile operating systems. For example Android and iOS ship with SQLite. It is also built into for example Firefox web browser. It is also often used with PHP. So SQLite is probably a pretty safe bet if you need relational database for an embedded system that needs to support SQL commands and does not need to store huge amounts of data (no need to modify database with millions of lines of data).

If you do not need relational database and you need very high performance, you need probably to look somewhere else.Berkeley DB (BDB) is a software library intended to provide a high-performance embedded database for key/value data. Berkeley DB is written in Cwith API bindings for many languages. BDB stores arbitrary key/data pairs as byte arrays. There also many other key/value database systems.

RTA (Run Time Access) gives easy runtime access to your program’s internal structures, arrays, and linked-lists as tables in a database. When using RTA, your UI programs think they are talking to a PostgreSQL database (PostgreSQL bindings for C and PHP work, as does command line tool psql), but instead of normal database file you are actually accessing internals of your software.

Software quality

Building quality into embedded software doesn’t happen by accident. Quality must be built-in from the beginning. Software startup checklist gives quality a head start article is a checklist for embedded software developers to make sure they kick-off their embedded software implementation phase the right way, with quality in mind

Safety

Traditional methods for achieving safety properties mostly originate from hardware-dominated systems. Nowdays more and more functionality is built using software – including safety critical functions. Software-intensive embedded systems require new approaches for safety. Embedded Software Can Kill But Are We Designing Safely?

IEC, FDA, FAA, NHTSA, SAE, IEEE, MISRA, and other professional agencies and societies work to create safety standards for engineering design. But are we following them? A survey of embedded design practices leads to some disturbing inferences about safety.Barr Group’s recent annual Embedded Systems Safety & Security Survey indicate that we all need to be concerned: Only 67 percent are designing to relevant safety standards, while 22 percent stated that they are not—and 11 percent did not even know if they were designing to a standard or not.

If you were the user of a safety-critical embedded device and learned that the designers had not followed best practices and safety standards in the design of the device, how worried would you be? I know I would be anxious, and quite frankly. This is quite disturbing.

Security

The advent of low-cost wireless connectivity is altering many things in embedded development – it has added to your list of worries need to worry about communication issues like breaks connections, latency and security issues. Understanding security is one thing; applying that understanding in a complete and consistent fashion to meet security goals is quite another. Embedded development presents the challenge of coding in a language that’s inherently insecure; and quality assurance does little to ensure security.

Developing Secure Embedded Software white paper  explains why some commonly used approaches to security typically fail:

MISCONCEPTION 1: SECURITY BY OBSCURITY IS A VALID STRATEGY
MISCONCEPTION 2: SECURITY FEATURES EQUAL SECURE SOFTWARE
MISCONCEPTION 3: RELIABILITY AND SAFETY EQUAL SECURITY
MISCONCEPTION 4: DEFENSIVE PROGRAMMING GUARANTEES SECURITY

Many organizations are only now becoming aware of the need to incorporate security into their software development lifecycle.

Some techniques for building security to embedded systems:

Use secure communications protocols and use VPN to secure communications
The use of Public Key Infrastructure (PKI) for boot-time and code authentication
Establishing a “chain of trust”
Process separation to partition critical code and memory spaces
Leveraging safety-certified code
Hardware enforced system partitioning with a trusted execution environment
Plan the system so that it can be easily and safely upgraded when needed

Flood of new languages

Rather than living and breathing C/C++, the new generation prefers more high-level, abstract languages (like Java, Python, JavaScript etc.). So there is a huge push to use interpreted and scripting also in embedded systems. Increased hardware performance on embedded devices combined with embedded Linux has made the use of many scripting languages good tools for implementing different parts of embedded applications (for example web user interface). Nowadays it is common to find embedded hardware devices, based on Raspberry Pi for instance, that are accessible via a network, run Linux and come with Apache and PHP installed on the device.  There are also many other relevant languages

One workable solution, especially for embedded Linux systems is that part of the activities organized by totetuettu is a C program instead of scripting languages ​​(Scripting). This enables editing operation simply script files by editing without the need to turn the whole system software again.  Scripting languages ​​are also tools that can be implemented, for example, a Web user interface more easily than with C / C ++ language. An empirical study found scripting languages (such as Python) more productive than conventional languages (such as C and Java) for a programming problem involving string manipulation and search in a dictionary.

Scripting languages ​​have been around for a couple of decades Linux and Unix server world standard tools. the proliferation of embedded Linux and resources to merge systems (memory, processor power) growth has made them a very viable tool for many embedded systems – for example, industrial systems, telecommunications equipment, IoT gateway, etc . Some of the command language is suitable for up well even in quite small embedded environments.
I have used with embedded systems successfully mm. Bash, AWK, PHP, Python and Lua scripting languages. It works really well and is really easy to make custom code quickly .It doesn’t require a complicated IDE; all you really need is a terminal – but if you want there are many IDEs that can be used.
High-level, dynamically typed languages, such as Python, Ruby and JavaScript. They’re easy—and even fun—to use. They lend themselves to code that easily can be reused and maintained.

There are some thing that needs to be considered when using scripting languages. Sometimes lack of static checking vs a regular compiler can cause problems to be thrown at run-time. But it is better off practicing “strong testing” than relying on strong typing. Other ownsides of these languages is that they tend to execute more slowly than static languages like C/C++, but for very many aplications they are more than adequate. Once you know your way around dynamic languages, as well the frameworks built in them, you get a sense of what runs quickly and what doesn’t.

Bash and other shell scipting

Shell commands are the native language of any Linux system. With the thousands of commands available for the command line user, how can you remember them all? The answer is, you don’t. The real power of the computer is its ability to do the work for you – the power of the shell script is the way to easily to automate things by writing scripts. Shell scripts are collections of Linux command line commands that are stored in a file. The shell can read this file and act on the commands as if they were typed at the keyboard.In addition to that shell also provides a variety of useful programming features that you are familar on other programming langauge (if, for, regex, etc..). Your scripts can be truly powerful. Creating a script extremely straight forward: It can be created by opening a separate editor such or you can do it through a terminal editor such as VI (or preferably some else more user friendly terminal editor). Many things on modern Linux systems rely on using scripts (for example starting and stopping different Linux services at right way).

One of the most useful tools when developing from within a Linux environment is the use of shell scripting. Scripting can help aid in setting up environment variables, performing repetitive and complex tasks and ensuring that errors are kept to a minimum. Since scripts are ran from within the terminal, any command or function that can be performed manually from a terminal can also be automated!

The most common type of shell script is a bash script. Bash is a commonly used scripting language for shell scripts. In BASH scripts (shell scripts written in BASH) users can use more than just BASH to write the script. There are commands that allow users to embed other scripting languages into a BASH script.

There are also other shells. For example many small embedded systems use BusyBox. BusyBox providesis software that provides several stripped-down Unix tools in a single executable file (more than 300 common command). It runs in a variety of POSIX environments such as Linux, Android and FreeeBSD. BusyBox become the de facto standard core user space toolset for embedded Linux devices and Linux distribution installers.

Shell scripting is a very powerful tool that I used a lot in Linux systems, both embedded systems and servers.

Lua

Lua is a lightweight  cross-platform multi-paradigm programming language designed primarily for embedded systems and clients. Lua was originally designed in 1993 as a language for extending software applications to meet the increasing demand for customization at the time. It provided the basic facilities of most procedural programming languages. Lua is intended to be embedded into other applications, and provides a C API for this purpose.

Lua has found many uses in many fields. For example in video game development, Lua is widely used as a scripting language by game programmers. Wireshark network packet analyzer allows protocol dissectors and post-dissector taps to be written in Lua – this is a good way to analyze your custom protocols.

There are also many embedded applications. LuCI, the default web interface for OpenWrt, is written primarily in Lua. NodeMCU is an open source hardware platform, which can run Lua directly on the ESP8266 Wi-Fi SoC. I have tested NodeMcu and found it very nice system.

PHP

PHP is a server-side HTML embedded scripting language. It provides web developers with a full suite of tools for building dynamic websites but can also be used as a general-purpose programming language. Nowadays it is common to find embedded hardware devices, based on Raspberry Pi for instance, that are accessible via a network, run Linux and come with Apache and PHP installed on the device. So on such enviroment is a good idea to take advantage of those built-in features for the applications they are good – for building web user interface. PHP is often embedded into HTML code, or it can be used in combination with various web template systems, web content management system and web frameworks. PHP code is usually processed by a PHP interpreter implemented as a module in the web server or as a Common Gateway Interface (CGI) executable.

Python

Python is a widely used high-level, general-purpose, interpreted, dynamic programming language. Its design philosophy emphasizes code readability. Python interpreters are available for installation on many operating systems, allowing Python code execution on a wide variety of systems. Many operating systems include Python as a standard component; the language ships for example with most Linux distributions.

Python is a multi-paradigm programming language: object-oriented programming and structured programming are fully supported, and there are a number of language features which support functional programming and aspect-oriented programming,  Many other paradigms are supported using extensions, including design by contract and logic programming.

Python is a remarkably powerful dynamic programming language that is used in a wide variety of application domains. Since 2003, Python has consistently ranked in the top ten most popular programming languages as measured by the TIOBE Programming Community Index. Large organizations that make use of Python include Google, Yahoo!, CERN, NASA. Python is used successfully in thousands of real world business applications around globally, including many large and mission-critical systems such as YouTube.com and Google.com.

Python was designed to be highly extensible. Libraries like NumPy, SciPy and Matplotlib allow the effective use of Python in scientific computing. Python is intended to be a highly readable language. Python can also be embedded in existing applications and hasbeen successfully embedded in a number of software products as a scripting language. Python can serve as a scripting language for web applications, e.g., via mod_wsgi for the Apache web server.

Python can be used in embedded, small or minimal hardware devices. Some modern embedded devices have enough memory and a fast enough CPU to run a typical Linux-based environment, for example, and running CPython on such devices is mostly a matter of compilation (or cross-compilation) and tuning. Various efforts have been made to make CPython more usable for embedded applications.

For more limited embedded devices, a re-engineered or adapted version of CPython, might be appropriateExamples of such implementations include the following: PyMite, Tiny Python, Viper. Sometimes the embedded environment is just too restrictive to support a Python virtual machine. In such cases, various Python tools can be employed for prototyping, with the eventual application or system code being generated and deployed on the device. Also MicroPython and tinypy have been ported Python to various small microcontrollers and architectures. Real world applications include Telit GSM/GPRS modules that allow writing the controlling application directly in a high-level open-sourced language: Python.

Python on embedded platforms? It is quick to develop apps, quick to debug – really easy to make custom code quickly. Sometimes lack of static checking vs a regular compiler can cause problems to be thrown at run-time. To avoid those try to have 100% test coverage. pychecker is a very useful too also which will catch quite a lot of common errors. The only downsides for embedded work is that sometimes python can be slow and sometimes it uses a lot of memory (relatively speaking). An empirical study found scripting languages (such as Python) more productive than conventional languages (such as C and Java) for a programming problem involving string manipulation and search in a dictionary. Memory consumption was often “better than Java and not much worse than C or C++”.

JavaScript and node.js

JavaScript is a very popular high-level language. Love it or hate it, JavaScript is a popular programming language for many, mainly because it’s so incredibly easy to learn. JavaScript’s reputation for providing users with beautiful, interactive websites isn’t where its usefulness ends. Nowadays, it’s also used to create mobile applications, cross-platform desktop software, and thanks to Node.js, it’s even capable of creating and running servers and databases!  There is huge community of developers. JavaScript is a high-level language.

Its event-driven architecture fits perfectly with how the world operates – we live in an event-driven world. This event-driven modality is also efficient when it comes to sensors.

Regardless of the obvious benefits, there is still, understandably, some debate as to whether JavaScript is really up to the task to replace traditional C/C++ software in Internet connected embedded systems.

It doesn’t require a complicated IDE; all you really need is a terminal.

JavaScript is a high-level language. While this usually means that it’s more human-readable and therefore more user-friendly, the downside is that this can also make it somewhat slower. Being slower definitely means that it may not be suitable for situations where timing and speed are critical.

JavaScript is already in embedded boards. You can run JavaScipt on Raspberry Pi and BeagleBone. There are also severa other popular JavaScript-enabled development boards to help get you started: The Espruino is a small microcontroller that runs JavaScript. The Tessel 2 is a development board that comes with integrated wi-fi, an ethernet port, two USB ports, and companion source library downloadable via the Node Package Manager. The Kinoma Create, dubbed the “JavaScript powered Internet of Things construction kit.”The best part is that, depending on the needs of your device, you can even compile your JavaScript code into C!

JavaScript for embedded systems is still in its infancy, but we suspect that some major advancements are on the horizon.We for example see a surprising amount of projects using Node.js.Node.js is an open-source, cross-platform runtime environment for developing server-side Web applications. Node.js has an event-driven architecture capable of asynchronous I/O that allows highly scalable servers without using threading, by using a simplified model of event-driven programming that uses callbacks to signal the completion of a task. The runtime environment interprets JavaScript using Google‘s V8 JavaScript engine.Node.js allows the creation of Web servers and networking tools using JavaScript and a collection of “modules” that handle various core functionality. Node.js’ package ecosystem, npm, is the largest ecosystem of open source libraries in the world. Modern desktop IDEs provide editing and debugging features specifically for Node.js applications

JXcore is a fork of Node.js targeting mobile devices and IoTs. JXcore is a framework for developing applications for mobile and embedded devices using JavaScript and leveraging the Node ecosystem (110,000 modules and counting)!

Why is it worth exploring node.js development in an embedded environment? JavaScript is a widely known language that was designed to deal with user interaction in a browser.The reasons to use Node.js for hardware are simple: it’s standardized, event driven, and has very high productivity: it’s dynamically typed, which makes it faster to write — perfectly suited for getting a hardware prototype out the door. For building a complete end-to-end IoT system, JavaScript is very portable programming system. Typically an IoT projects require “things” to communicate with other “things” or applications. The huge number of modules available in Node.js makes it easier to generate interfaces – For example, the HTTP module allows you to create easily an HTTP server that can easily map the GET method specific URLs to your software function calls. If your embedded platform has ready made Node.js support available, you should definately consider using it.

Future trends

According to New approaches to dominate in embedded development article there will be several camps of embedded development in the future:

One camp will be the traditional embedded developer, working as always to craft designs for specific applications that require the fine tuning. These are most likely to be high-performance, low-volume systems or else fixed-function, high-volume systems where cost is everything.

Another camp might be the embedded developer who is creating a platform on which other developers will build applications. These platforms might be general-purpose designs like the Arduino, or specialty designs such as a virtual PLC system.

This third camp is likely to become huge: Traditional embedded development cannot produce new designs in the quantities and at the rate needed to deliver the 50 billion IoT devices predicted by 2020.

Transition will take time. The enviroment is different than computer and mobile world. There are too many application areas with too widely varying requirements for a one-size-fits-all platform to arise.

But the shift will happen as hardware becomes powerful and cheap enough that the inefficiencies of platform-based products become moot.

 

Sources

Most important information sources:

New approaches to dominate in embedded development

A New Approach for Distributed Computing in Embedded Systems

New Approaches to Systems Engineering and Embedded Software Development

Lua (programming language)

Embracing Java for the Internet of Things

Node.js

Wikipedia Node.js

Writing Shell Scripts

Embedded Linux – Shell Scripting 101

Embedded Linux – Shell Scripting 102

Embedding Other Languages in BASH Scripts

PHP Integration with Embedded Hardware Device Sensors – PHP Classes blog

PHP

Python (programming language)

JavaScript: The Perfect Language for the Internet of Things (IoT)

Node.js for Embedded Systems

Embedded Python

MicroPython – Embedded Pytho

Anyone using Python for embedded projects?

Telit Programming Python

JavaScript: The Perfect Language for the Internet of Things (IoT)

MICROCONTROLLERS AND NODE.JS, NATURALLY

Node.js for Embedded Systems

Why node.js?

Node.JS Appliances on Embedded Linux Devices

The smartest way to program smart things: Node.js

Embedded Software Can Kill But Are We Designing Safely?

DEVELOPING SECURE EMBEDDED SOFTWARE

 

 

 

1,667 Comments

  1. Tomi Engdahl says:

    Run mainline Linux on 5 dollar hardware
    https://blog.adafruit.com/2024/04/09/run-mainline-linux-on-5-dollar-hardware/

    Uros Popovic looks to run mainline Linux on $5 dollar hardware (well, if it’s the board above, $11.70). The Lichee Nano is an SD card sized Linux development board powered by an Allwinner F1C100s ARM9 processor.

    Reply
  2. Tomi Engdahl says:

    Unlocking Possibilities: 4 Reasons Why ESP32 and Rust Make a Winning Combination
    https://dev.to/apollolabsbin/unlocking-possibilities-4-reasons-why-esp32-and-rust-make-a-winning-combination-4kbl

    Rust has gained significant attention and popularity among developers due to its robustness, memory safety guarantees, and emphasis on performance. However, beyond being a language, Rust is also a thriving programming project with a vibrant community and an extensive ecosystem of tools and libraries. The Rust project encompasses not only the language’s development and maintenance but also various related initiatives that aim to enhance its usability, foster collaboration, and promote its adoption. From the Rust compiler to package managers, build systems, and testing frameworks, the Rust project embodies a collective effort to empower developers with a reliable and efficient programming environment, enabling them to tackle complex software projects with confidence.

    Reply
  3. Tomi Engdahl says:

    https://etn.fi/index.php/tekniset-artikkelit/16091-naein-toimii-autonominen-turva-autonomisessa-jaerjestelmaessae

    Tekoälyn ja koneoppimistekniikoiden nopeasti yleistyvä käyttöönotto yhä autonomisemmissa järjestelmissä lisää vaatimuksia entistä älykkäämmille turvajärjestelmille useilla eri teollisuusaloilla. Painopiste on samalla siirtymässä kustannussäästöistä käyttömukavuuteen ja turvallisuuteen.

    Artikkelin kirjoittaja Bob Martin toimii Microchip Technology -yhtiössä sulautettujen järjestelmien vanhempana suunnitteluinsinöörinä.

    Tämä kehitys vaatii järjestelmältä täydellisen toiminnallisuuden tarjoavan kerroksen (FuSa), joka koostuu turvaprosessorista ja luotettavista I/O-ohjaimista, jotka toimivat yhdessä järjestelmän suojaamiseksi. Mikro-ohjaimet (MCU) tarjoavat edullisen ratkaisun toteuttaa nämä turvallisuuden takaavat oheisprosessorit, jotka ovat uuden sukupolven autonomisten järjestelmien ytimessä.

    Reply
  4. Tomi Engdahl says:

    Entware
    This is a software repository for network attached storages, routers and other embedded devices.
    https://entware.net/about.html

    Reply
  5. Tomi Engdahl says:

    When to choose Linux over an RTOS?
    https://www.reddit.com/r/embedded/comments/qus40i/when_to_choose_linux_over_an_rtos/

    Which operating system is best suited for your embedded systems project – FreeRTOS or Linux?
    https://www.bytesnap.com/news-blog/freertos-vs-linux-embedded-systems/

    Reply
  6. Tomi Engdahl says:

    Säästätkö yrityksesi hengiltä? Ohjelmistojen kehityksessä säästäminen luo teknistä velkaa
    https://www.hurja.fi/blogi/ohjelmistojen-kehityksessa-saastaminen-luo-teknista-velkaa/

    Reply
  7. Tomi Engdahl says:

    Curated list of resources for ESP32 development in the Rust programming language
    https://github.com/esp-rs/awesome-esp-rust

    Reply
  8. Tomi Engdahl says:

    Human-Interfacing Devices: HID Over I2C
    https://hackaday.com/2024/04/17/human-interfacing-devices-hid-over-i2c/

    This time, let’s talk about an underappreciated HID standard, but one that you might be using right now as you’re reading this article – I2C-HID, or HID over I2C.

    HID as a protocol can be tunneled over many different channels. If you’ve used a Bluetooth keyboard, for instance, you’ve used tunneled HID. For about ten years now, I2C-HID has been heavily present in laptop space, it was initially used in touchpads, later in touchscreens, and now also in sensor hubs. Yes, you can expose sensor data over HID, and if you have a clamshell (foldable) laptop, that’s how the rotation-determining accelerometer exposes its data to your OS.

    Not every I2C-connected input device is I2C-HID. For instance, if you’ve seen older tablets with I2C-connected touchscreens, don’t get your hopes up, as they likely don’t use HID – it’s just a complex-ish I2C device, with enough proprietary registers and commands to drive you crazy even if your logic analysis skills are on point. I2C-HID is nowhere near that, and it’s also way better than PS/2 we used before – an x86-only interface with limited capabilities, already almost extinct from even x86 boards, and further threatened in this increasingly RISCy world. I2C-HID is low-power, especially compared to USB, as capable as HID goes, compatible with existing HID software, and ubiquitous enough that you surely already have an I2C port available on your SBC.

    Human-Interfacing Devices: Packing For The Descriptor Heist
    https://hackaday.com/2024/02/06/human-interfacing-devices-packing-for-the-descriptor-heist/

    Reply
  9. Tomi Engdahl says:

    MLCommons Releases Latest MLPerf Tiny Benchmark Results for On-Device TinyML
    Devices from Bosch, Qualcomm, Renesas, STMicro, Skymizer, and Syntiant put to test in the latest MLPerf Tiny 1.2 benchmark.
    https://www.hackster.io/news/mlcommons-releases-latest-mlperf-tiny-benchmark-results-for-on-device-tinyml-3f820ae12aae

    Reply
  10. Tomi Engdahl says:

    Chinese researchers use low-cost Nvidia chip for hypersonic weapon —unrestricted Nvidia Jetson TX2i powers guidance system
    News
    By Anton Shilov published 3 days ago
    1.26 FP16 TFLOPS is good enough for fluid dynamics.
    https://www.tomshardware.com/tech-industry/artificial-intelligence/chinese-researchers-install-low-cost-unrestricted-nvidia-jetson-tx2i-into-hypersonic-weapon

    Reply
  11. Tomi Engdahl says:

    Italialainen SECO to Qualcommin IoT-piirit moduuleihin
    https://etn.fi/index.php/new-products/16122-italialainen-seco-to-qualcommin-iot-piirit-moduuleihin

    Italian Arezzossa päämajaansa pitävä SECO on esitellyt ensimmäiset SMARC-moduulinsa, jotka perustuvat Qualcommin QCS6490- ja QCS5430-sovellusprosessoreihin. Nämä uudet SMARC-moduulit ovat ensimmäisiä tuloksia yhtiöiden strategisesta yhteistyöstä, josta ilmoitettiin viime vuoden syyskuussa.

    Yhteistyön tavoitteena on nopeuttaa verkon reunalla toimivien tuotteiden kehittämistä teollisen IoT:n maailmaan. SOM-SMARC-QCS6490 yksinkertaistaa Qualcommin QCS6490-prosessorin käyttöä, joka on Qualcommin IoT:een räätälöity premium-tason alusta. Piirisarja tarjoaa tukea tekoälylle ja vankkaa suorituskykyä pienellä virrankulutuksella sekä laajennettuja liitäntöjä ja oheislaitteita, jotka soveltuvat erilaisiin teollisuuden käyttötarkoituksiin.

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  12. Tomi Engdahl says:

    Tämä laite pitäisi olla jokaisen suunnittelijan pöydällä
    https://etn.fi/index.php/13-news/16140-taemae-laite-pitaeisi-olla-jokaisen-suunnittelijan-poeydaellae

    Ruotsalainen Qoitech irrotettiin vuonna 2019 Sonystä kaupallistamaan työkalu, joka pitäisi olla jokaisen suunnittelijan työpöydällä. Yhtiölla on kaksi teholähdettä ja niihin liitetty ohjelmisto, joilla voidaan profiloida IoT-laitteiden tehonkulutusprofiileja.

    Perustaja ja toimitusjohtaja Vanja Samuelssonin mukaan Qoitechin Otii-laitteet korvaavat suunnittelijan työpöydällä kalliita analysaattoreita, jotka tulevat suurilta mittauslaitetaloilta. Otii Arc Pro yltää 5 voltin teholähteeksi ja maksaa 899 dollaria. 25 volttiin yltävä Otii Ace Pro maksaa 1599 dollaria.

    Laitteet toimivat yhtä aikaa sekä teholähteinä että analysaattoreina. Arc Pro näytteistää virtaa 4000 kerta sekunnissa, Ace Pro 50 000 kertaa sekunnissa. Arc Pro voidaan asettaa jatkuvaksi, lineaariseksi virtalähteeksi. Sitä voidaan käyttää tehoanalysaattorina tai profilaattorina reaaliaikaisten virtojen, jännitteiden ja/tai UART-lokien tallentamiseen ja näyttämiseen. Mittaustarkkuus on nanoampeereja. Ace Prossa tarkkuus on alle nanoampeerien luokkaa. Molempien laitteiden ohjelmisto voi nyt hankkia samaan hintaan 199 dollarin vuosilisenssillä ja uusi 3.5-versio tukee suoraan myös kaikkia vanhoja Pro-toimintoja.

    Reply
  13. Tomi Engdahl says:

    A Smart Power Distribution Unit For Home Automation
    https://hackaday.com/2024/04/25/a-smart-power-distribution-unit-for-home-automation/

    Power distribution units, as the name implies, are indispensable tools to have available in a server rack. They can handle a huge amount of power for demands of intensive computing and do it in a way that the wiring is managed fairly well. Plenty of off-the-shelf solutions have remote control or automation capabilities as well, but finding none that fit [fmarzocca]’s needs or price range, he ended up building his own essentially from scratch that powers his home automation system.

    Because it is the power supply for a home automation system, each of the twelve outlets in this unit needed to be individually controllable. For that, three four-channel relay boards were used, each driven by an output on an ESP32. The ESP32 is running the Tasmota firmware to keep from having to reinvent the wheel, while MQTT was chosen as a protocol for controlling these outlets to allow for easy integration with the existing Node-RED-based home automation system. Not only is control built in to each channel, but the system can monitor the power consumption of each outlet individually as well. The entire system is housed in a custom-built sheet metal enclosure and painted to blend in well with any server rack.

    https://www.instructables.com/Sen6-PDU-a-Smart-Power-Distribution-Unit/

    Reply
  14. Tomi Engdahl says:

    Glen Akins’ Bike Rack Gets Smart Yet Accessible Lighting, Thanks to Zigbee, MQTT, and Python
    Powered by a Nordic nRF52840, a simple pair of satisfyingly-chunky push buttons uses Zigbee, MQTT, and Python to tame smart lighting.
    https://www.hackster.io/news/glen-akins-bike-rack-gets-smart-yet-accessible-lighting-thanks-to-zigbee-mqtt-and-python-7607ccc60d71

    Reply
  15. Tomi Engdahl says:

    The Future of the Human–Machine Interface (HMI) in Society 5.0
    https://www.mdpi.com/1999-5903/15/5/162?utm_campaign=journnews_ccbj_futureinternet&utm_medium=social_journ&utm_source=facebook&fbclid=IwAR3_u_wFw0O_WZDU0Ad5QnS4ovk9ukiX2M0tg75VTu5pi9YA40jDYNnoHNQ_aem_AemiEy3rLSmehEVuob1uyDuJ012sy7O_Xtx2eaOQiavZ2s-Lqz1-sZ2cCqm3c1CGB9sbTep96w8IoNrdAdE7SLK1

    The blending of human and mechanical capabilities has become a reality in the realm of Industry 4.0. Enterprises are encouraged to design frameworks capable of harnessing the power of human and technological resources to enhance the era of Artificial Intelligence (AI). Over the past decade, AI technologies have transformed the competitive landscape, particularly during the pandemic. Consequently, the job market, at an international level, is transforming towards the integration of suitably skilled people in cutting edge technologies, emphasizing the need to focus on the upcoming super-smart society known as Society 5.0. The concept of a Humachine builds on the notion that humans and machines have a common future that capitalizes on the strengths of both humans and machines. Therefore, the aim of this paper is to identify the capabilities and distinguishing characteristics of both humans and machines, laying the groundwork for improving human–machine interaction (HMI).
    Keywords: human–machine interface; HMI; Society 5.0; Industry 5.0; Artificial Intelligence (AI)

    Reply
  16. Tomi Engdahl says:

    Software-defined automation is believed to completely change how automation is done and what it looks like. One of the most important changes to look forward to is that SDA has even more benefits for industries than before.

    “At the moment, SDA’s benefits are not directly aimed at reducing costs. Instead, it is opening the ecosystem to connect the world pretty much from the device and factory floor level. The added value comes from interoperability and bringing together multiple blocks easily,” says Daniel Rogoz, head of Etteplan’s embedded systems in Poland.

    Learn more about the benefits of the software-defined automation from the article!

    #SoftwareDefinedAutomation

    Reply
  17. Tomi Engdahl says:

    SDA and hardware agnostics disrupt the world of industrial automation
    In industrial automation, equipment has always been tightly coupled with closed and proprietary software. A new era of software-defined automation (SDA) and hardware agnostics is about to begin, decoupling applications and hardware from each other. This means a significant transformation that benefits both developers and owners of automation systems.

    https://www.etteplan.com/about-us/insights/sda-and-hardware-agnostics-disrupt-the-world-of-industrial-automation/?utm_source=facebook&utm_medium=paid&utm_campaign=SES_SDA24-04-06en&utm_content=articlehardware-agnostics&fbclid=IwAR0oiJZkYP8SUHiMA3_CNbPhFgRY2SJhz-ReU6ZHjUlkMF6m0mR9Kg2NdB0_aem_ATjK8uiKnd9ub3Oh22vZfJBP_8kTNRNccH5nRdKn4rZZuRBYJjn9x3ipuRoh4sI_I-52-KgUJb4Q2SCeRZhkOtKO

    Reply
  18. Tomi Engdahl says:

    https://etn.fi/index.php/13-news/16152-edullisesti-rautatason-salaus-mikro-ohjaimeen

    Tänä vuonna voimaan tuleva lainsäädäntö velvoittaa tiukemmat kyberturvallisuusvaatimukset kaikkeen elektroniikkaan kuluttajien IoT-laitteista kriittiseen infrastruktuuriin. Microchip vastaa haasteeseen uusilla 32-bittisillä ohjainpiireillään.

    Uusi ohjainperhe on PIC32CK ja sen siruilla on integroitu laitteistopohjainen HSM-turvamoduuli. Ohjainten Arm Cortex-M33 -ytimeltä löytyy Arm:n TrustZone-tekniikka, joka eristää vaadittavat osat piirillä.

    Reply
  19. Tomi Engdahl says:

    Generatiivinen tekoäly tulee IoT-laitteisiin
    https://etn.fi/index.php/13-news/16169-generatiivinen-tekoaely-tulee-iot-laitteisiin

    Englantilaislähtöisellä Arm:.a on oma neuroverkkoprosessorien sarja, joka on nimeltään Ethos. Nyt perheeseen on tuotu uusi versio. Ethos-U85 on suunniteltu tukemaan muuntaja- eli transformer-toimintoja vähävirtaisissa laitteissa. Käytännössä Arm tuo generatiiviset tekoälymallit IoT-laitteisiin.

    Kannattaa toki muistaa, etteivät IoT-laitteet jatkossakaan kykene prosessoimaan suuria kielimalleja eli LLM-malleille perustuvaa tekoälylaskentaa. Tässä vaiheessa Arm kertoo siirtäneensä esimerkiksi konenäkömalli ViT-Tinyn ja generatiivisen kielimallin TinyLlama-1.1B Ethos-U85-piirille.

    Ethos-U85:sta puhuttiin paljon jo kuukausi sitten Nürnbergin Embedded World -messuilla. Moni Arm:n asiakas hehkutti uutta NPU-yksikköä ja kertoi jo tuovansa sitä omille siruilleen. Julkisesti asiasta ei tietenkään saanut vielä puhua.

    Ethos-U85:ssä on kolmannen sukupolven mikroarkkitehtuuri. Toisen sukupolven U65:een verrattuna U85 on suurimmassa kokoonpanossaan 4 kertaa tehokkaampi ja 20 prosenttia energiatehokkaampi.

    Reply
  20. Tomi Engdahl says:

    Uutuussiru ohjaa tarkasti auton sähköjärjestelmää
    https://etn.fi/index.php/13-news/16172-uutuussiru-ohjaa-tarkasti-auton-saehkoejaerjestelmaeae

    Infineon on esitellyt PSoC 4 -sarjaan ohjainpiirin, jolle on integroitu tarkka analogiaosa korkeajännitteiden alijärjestelmien ohjaamiseen. Piiri on käytännössä yhden sirun ratkaisu 12 voltin lyijyakkujen valvontaan ja hallintaan. Ohjain on ISO26262-yhteensopiva, mikä mahdollistaa kompaktin ja turvallisen älykkään akun tunnistuksen ja akunhallinnan nykyaikaisissa ajoneuvoissa.

    PSoC 4 HVPA-144K-piirillä on kaksi tarkkaa sigma-delta -AD-muunninta, jotka yhdessä neljän digitaalisen suodatuskanavan kanssa mahdollistavat akun varaustilan (SoC) ja terveydentilan (SoH) tarkan mittauksen. Siru mittaa tärkeitä parametreja, kuten jännitettä, virtaa ja lämpötilaa jopa ±0,1 prosentin tarkkuudella.

    Reply
  21. Tomi Engdahl says:

    Your Pi, From Anywhere
    https://hackaday.com/2024/05/07/your-pi-from-anywhere/

    The Raspberry Pi finds a use in a huge variety of applications, and in almost any location you could imagine. Sadly those who use those machines might not be in the same place as the machines themselves, and thus there’s the question of providing a remote connection between the two. This may not be a huge challenge to those skilled with Linux and firewalls, but to many Pi users it’s a closed book. So the Pi folks have come up with a painless way to connect to your Pi wherever it is, and it’s called Raspberry Pi Connect.

    To use the service all you need is a Pi running the latest 64-bit version of Raspberry Pi OS, so sadly that excludes base model Zeros and older models. Sign in to the Raspberry Pi Connect server, follow the instructions, and you’re on your way. Under the hood it’s the well-known VNC protocol at work, with the connection setup being managed via WebRTC. The Pi servers are intended to act simply as connection facilitators for peer-to-peer traffic, though they are capable of handling through traffic themselves. It’s a beta service with a single server in the UK at the time of writing, though we’d expect both the number of servers and the offering to evolve over time.

    https://www.raspberrypi.com/news/raspberry-pi-connect/

    Reply
  22. Tomi Engdahl says:

    https://learn.adafruit.com/adafruit-pdm-microphone-breakout/overview

    The first thing to note is that this sensor does not provide an ‘analog’ output like many of our electret microphone assemblies. So it’s great for chips that do not have analog inputs. Secondly, the digital interface is a very simplistic pulse density modulation output. It’s digital but its not PWM and it’s not I2S. You will need to make sure your chip has a PDM interface – most 32-bit processors these days do!

    PDM is a little like 1-bit PWM. You clock the mic with a 1 MHz – 3 MHz clock rate, and on the data line you’ll get a square wave out that syncs with the clock. The data line with be 0 or 1 logic output, with the square wave creating a density that when averaged will result in the analog value out.

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  23. Tomi Engdahl says:

    Understanding PDM Digital Audio
    https://users.ece.utexas.edu/~bevans/courses/rtdsp/lectures/10_Data_Conversion/AP_Understanding_PDM_Digital_Audio.pdf

    How can I convert an audio PDM bitstream into analog form?
    https://electronics.stackexchange.com/questions/521799/how-can-i-convert-an-audio-pdm-bitstream-into-analog-form

    I have collected PDM bitstreams from MEMS microphones and I’m looking to convert them into analogue form. Does anyone know some practical implementation details on how to do this (beyond a quote from Wikipedia that states this only requires a low pass filter)?

    Reply
  24. Tomi Engdahl says:

    https://github.com/jaycordaro/pdmbrd

    KiCAD 6.x board with two FAN3852 PDM analog to digital converters (ADCs).
    Features

    Converts analog audio and ultrasound signals into digital Pulse Density Modulation (PDM) format

    Jumper selection for different options

    Accepts analog input signals from SMA connectors, jumper wire, or 3.5mm (1/8″) stereo jack

    On-board low noise LT3042 voltage regulator (U1) powered from USB Micro provides 3.3V or 1.8V to the ADCs

    Board can be (mostly) assembled by JLCPCB (only U2 and UJ3 FAN3852 and J16 CUI SJ-3523-SMT audio jack need hand soldering)

    Much cheaper than OnSemi FAN3852 EVB

    Reply
  25. Tomi Engdahl says:

    Displays We Love Hacking: LVDS And EDP
    https://hackaday.com/2024/05/08/displays-we-love-hacking-lvds-and-edp/

    There are times when tiny displays no longer cut it. Whether you want to build a tablet or reuse some laptop displays, you will eventually deal with LVDS and eDP displays. To be more exact, these are displays that want you to use either LVDS or eDP signaling to send a picture.

    Of the two, LVDS is the older standard for connecting displays, and eDP is the newer one. In fact, eDP has mostly replaced LVDS for things like laptop and tablet displays. Nevertheless, you will still encounter both of these in the wild, so let’s start with LVDS.

    Reply
  26. Tomi Engdahl says:

    Embedded Software Sessions – Special Edition from Embedded World – Explore SimpleSwitch™
    https://youtu.be/_MfzahwJmus
    https://youtu.be/_MfzahwJmus?si=qgHX4-FqPCIf4-or

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