Infineon CY8CKIT-062S2-AI Dev Kit is a PSoC 62S2 MCU-powered development board built to create and test edge AI applications. The unique aspect of this board is that it features a plethora of sensors including a microphone, radar, IMU, magnetometer, and an air pressure sensor which can be configured to get environmental data, and with the help of a prebuilt AI model that data can be processed very easily.
In terms of connectivity the board has Wi-Fi and Bluetooth connectivity and complementing that is an additional expansion header that can be used to connect extra sensors and modules. This feature with an AI-compatible processor makes this device useful for applications like industrial monitoring, wearables, healthcare devices, robotics, and more.
The most unique aspect of this board is its software support as it comes with ready-to-use machine learning models which makes it easy to develop Edge AI applications around it, also it has support for ModusToolbox, Infineon’s software tool for embedded development and we have seen it used in the PSoC 64 IoT Security Workshop Development Kit. The board also supports the Imagimob Studio platform with which you can create machine-learning models and use them on small devices.
Infineon CY8CKIT-062S2-AI Dev Kit Specifications
MCU: PSoC 62S2 (Arm Cortex-M4F and Cortex-M0+, up to 1MB Flash, 288KB SRAM)
Wireless: Murata LBEE5KL1YN-814 (Wi-Fi 4, Bluetooth 5.2)
The Infineon CY8CKIT-062S2-AI Dev Kit also supports TensorFlow Lite Micro and neural network acceleration via CMSIS-DSP and CMSIS-NN libraries. This, combined with MQTT, HTTP, and AIROC Bluetooth connectivity, facilitates rapid prototyping and AI application development. The kit is available for purchase at $37.50 on Mouser Electronics and $50 on DigiKey.
The LILYGO T-Encoder-Pro is an ESP32-S3-based rotary encoder with a 1.2-inch AMOLED touchscreen display. The touchscreen features a 390×390 pixels resolution and has a pair of Qwiic connectors for additional peripheral support. The device also includes an onboard buzzer for auditory feedback, a USB Type-C port for data and power, and three threaded brass inserts for mounting, there’s also a push-button for resetting and programming.
In our previous post, we also wrote about MATOUCH, an ESP32-S3-based rotary display module. The device features a 2.1” IPS display with 480×480 pixels resolution and the display has a 75FPS refresh rate with a 65K color range. Feel free to check this out if you are looking for similar but more powerful products than this one.
The device can be programmed with both platforms or Arduino for programming using the Arduino GFX library for the AMOLED display driver, SensorLib for the touchscreen controller, and Lvgl library for graphics design. More details about the device including basic instructions, datasheet, board schematic in PDF, an Arduino pinout, and settings instructions can be found on GitHub.
The LILYGO T-Encoder-Pro is available on AliExpress at $33.98 with free shipping. It’s also listed on Amazon at $38, and on its official LILYGO store for $32.29, but it’s out of stock in all locations. You can check its official site for Shipping & Delivery time.
The ASUS Chromebox 5a is a compact mini PC with 13th-generation Intel Core processors. The PC comes in many configurations starting with Intel Celeron to Intel Core I7; the basic Celeron version only costs around $294.00, and the features pack i7 version will cost you around $980.00. The common thing about all these versions is that all support up to four 4K@60Hz displays and include an M.2 2280 PCIe slot for storage. In terms of RAM, it has a single SO-DIMM slot that supports up to 16GB of DDR4 memory.
This Chromebox can drive up to four 4K displays using dual HDMI, DisplayPort, and USB-C3.2 Gen2 DP ports, ideal for multi-monitor setups and media centers. It features Intel Wi-Fi 6E, and Bluetooth 5.3, and supports up to 1GbE networking, which is a divergence from the ASUS Chromebox 5 with its 2.5GbE port.
This Chromebox also supports 1GbE Ethernet, Wi-Fi 6E, and Bluetooth 5.3 connectivity. Ports include USB 3.2 Gen2/Gen1 Type-A, audio jack, microSD slot, USB-C with DP1.4/PD, and DC-in.
The Chromebox comes with many different accessories like the AC adapter, power cord, user manual, and warranty card. For those who need them, a keyboard and mouse, a screw pack for additional storage expansion, and a VESA mount for versatile setup options are available separately.
The ASUS Chromebox 5A offers various configurations to suit different needs and budgets. Prices start at $294 for the Celeron model with 4GB RAM/128GB SSD, going up to $515 for the Core i3 with 8GB RAM/128GB SSD. The Core i5, also with 8GB RAM/128GB SSD, costs $660. The top-end Core i7 model boasts 16GB RAM and 256GB SSD for $980.
The Palmshell PuER N1 Mini PC or networking PC is an Intel Celeron J6412-based PC with four 2.5GbE ports up to 32GB DDR4 RAM, and multiple storage options including M.2 and SATA. Additionally, it has Wi-Fi 6E, Bluetooth 5.2, and optional 4G/5G connectivity. Other features of this PC include HDMI 2.0, USB ports, and a custom cooling system. All these features make this PC useful for applications like network attached storage(NAS), home routers, SDN, Home Server, and much more.
The Intel Celeron J6412 used in this networking PC is a 10th-generation Quad-core processor with 4 cores and 4 threads, with a base clock speed of 2.0 GHz and a boost clock speed of 2.6 GHz. It has 1.5 MB of L2 cache and a 10W of TDP. It also has Intel UHD Graphics for 10th Gen with a maximum frequency of 800 MHz and 16 execution units.
The company mentions that this networking PC supports up to 32GB of dual-channel DDR4 memory at 3200 MT/s and can be purchased with or without memory. In terms of storage, the mini PC supports up to 256GB to 1TB of SSD. Additionally, a SATA 7-pin connector is provided for further storage expansion. other features include four 2.5GbE RJ45 Ethernet ports supported by Intel I225 ethernet controller it also supports link aggregation, which facilitates fast data transfers.
The device supports 4K output via HDMI 2.0, on top of that it offers USB 3.1/2.0 ports, it also has a copper heatsink with a fan for cooling, and supports Wi-Fi 6E, Bluetooth 5.2, and 4G/5G modules.
Intel UHD Graphics for 10th Gen Intel Processors (up to 800 MHz)
Memory:
Up to 32 GB DDR4@3200MT/s SO-DIMM (Dual-channel)
Configurations: 8GB, 16GB, 32GB
Storage:
1x M.2 M Key for SATA SSD
Configurations: 256GB, 512GB, 1TB SSD (SATA)
1x SATA 7-pin connector
Networking:
4x 2.5GbE RJ45 Ports (Intel I225)
Support link aggregation
1x M.2 E Key for Wi-Fi 6E/BT 5.2 Module (Intel AX210NGW)
1x M.2 B Key for 4G/5G Module
Display:
1x HDMI 2.0 (up to 4K)
USB:
2x USB 3.1
2x USB 2.0
Other I/O:
Power input: 12V DC 5525, at least 36W (power supply not included)
Dimensions & Weight:
Enclosure dimensions: TBD
Weight: TBD
Operating System:
Supports nearly all operating systems compatible with the x86 architecture (including ROOBI OS)
Additional Notes:
Custom copper heatsink with 3000 RPM PWM speed control fan (TDP 25W)
Barebone and pre-configured models are available
Pricing and availability TBD
Dimensions: Not Mentioned
The company mentions that the Networking PC supports mostly all operating systems that are compatible with the x86 architecture. The module also supports ROOBI OS, which works with both the SLiM X2L and the ROCK 5 ITX. more information about this can be found on the company’s wiki page.
At the time of writing the Palmshell PuER N1 Mini PC is not yet available for purchase but more information can be found on their products page or you can check out the Palmshell website for more information.
The Orange Pi 3B V2.1 is a Rockchip RK3566 SBC with WiFi 5 and Bluetooth 5, MicroSD, Gigabit Ethernet, USB, and more. The board also supports 2280 NVMe or SATA SSDs which is slightly larger than what we found in Orange Pi 3B SBC. Speaking of the Orange Pi 3B it was the first SBC powered by a Rockchip SoC, making the Pi 3B V2.1 the second board from the Orange Pi Foundation that utilizes a Rockchip SoC.
In terms of network connectivity, the board features Gigabit Ethernet and Wi-Fi, the interesting thing about Wi-Fi is that it features AP6256 WiFi 5 and Bluetooth 5 wireless module but previously we have always seen that Orange Pi always uses Allwinner AW859A-based CDTech 20U5622 module.
The Rockchip RK3566 used in the SBC features a quad-core Cortex-A55 processor with Arm Mali-G52 2EE GPU, and a 0.8 TOPS NPU, making it suitable for various applications including AI acceleration.
The board also has eMMC storage, SPI flash, a MicroSD card slot, and an M.2 M-key socket. It provides HDMI 2.0 for video output up to 4Kp60, MIPI DSI and eDP 1.3 connectors for displays, and a MIPI CSI connector for cameras. Additionally, for DIY projects sensors and inputs the board features multiple USB ports, a 40-pin GPIO header for expansion, and supports various operating systems like Android 11, Ubuntu, Debian, and OpenHarmony.
Orange Pi 3B V2.1 specifications:
Processor: Rockchip RK3566 quad-core 64-bit (22nm, up to 1.8GHz)
Graphics: ARM Mali G52 2EE graphics processor with support OpenGL ES 1.1/2.0/3.2, OpenCL 2.0 and Vulkan 1.1
NPU: Integrated RKNN NPU AI accelerator with 0.8Tops@INT8
Video:
Supports 4K@60fps H.265/H.264/VP9 video decoding
1080P@100fps H.265 video encoding
1080P@60fps H.264 video encoding
Memory: Options of 2GB/4GB/8GB (LPDDR4/4X)
Storage:
Support eMMC up to 256GB
16MB or 32MB SPI flash
M.2 M-KEY socket for SATA3 or PCIe2.0 NVME SSDs
Micro SD socket
Connectivity:
Gigabit Ethernet
Dual-band WiFi 5 and Bluetooth 5 via Ampak AP6256 wireless module
Display/Audio:
HDMI 2.0 supports up to 4K@60fps
2-lane MIPI DSI connector
eDP1.3
3.5mm headphone jack for audio in/out
Camera: MIPI CSI 2-lane camera interface
USB:
1 x USB 2.0 support Device or HOST mode
1 x USB 3.0 HOST
1 x USB 2.0 HOST
Expansion: 40-pin GPIO header with UART, SPI, I2C, PWM
OSSupport: Android 11, Ubuntu 22.04, Ubuntu 20.04, Debian 11, Debian 12, OpenHarmony 4.0 Beta1, Orange Pi OS (Arch), Orange Pi OS (OH) based on OpenHarmony and other operating systems.
An Orange Pi 3B V2.1 can be used in multiple ways from TV boxes to high-end tablets, edge computing, recognition of face, smart security, smart home, and many others. You’ll find more details on the Download page.
The new Orange Pi 3B V2.1 can be purchased from Amazon for $40.99 with shipping in the USA, and on Aliexpress for $30 with the final price depending on the selected configuration.
Autosport Labs, a company renowned for its motorsport acquisition and real-time telemetry products, has introduced the ESP32-CAN-X2 board. This board features an ESP32-S3 microcontroller, dual CAN bus interfaces, and an automotive-grade power supply capable of handling a 6V to 20V DC input range.
ESP32 boards with CAN bus capabilities are not new, with predecessors like the Olimex ESP32-EVB Board, CAN32, CanLite ESP32, and RejsaCAN-ESP32-S3 paving the way. The ESP32-CAN-X2, however, stands out by incorporating two CAN bus interfaces alongside the ESP32-S3 microcontroller, offering enhanced functionality for automotive and industrial applications.
ESP32-CAN-X2 Board Specifications
Wireless Module: ESP32-S3-WROOM-1-N8R8
MCU: ESP32-S3 dual-core Tensilica LX7 microcontroller up to 240 MHz with 384KB ROM, 512KB SRAM, and 16 KB SRAM in RTC
Memory: 8MB PSRAM
Storage: 8MB flash
Wireless: WiFi 4 and Bluetooth LE 5, with a PCB antenna
USB: USB Type-C port for flashing and power
CAN Bus:
6-pin header for 2x CAN V2.0B communication
1x CAN bus integrated into the ESP32-S3 MCU
1x CAN bus provided through MCP2515 connected over SPI
Integrated CAN transceivers
Configurable CAN termination resistors, disabled via breakable jumpers
Expansion: All pins broken out to a DIP form factor, supporting future stackable “bolt-ons” add-on boards
Miscellaneous:
Power LED, user LED
Reset and Boot push buttons
Automotive-grade Power Supply:
6-20V DC input via USB-C port or VIN pin, with peaks up to 40V Vmax
3.3V voltage regulator
Power consumption: 330mW typical, up to 1.65W
Dimensions: 72 x 42.10 mm
Temperature Range: -40°C to +85°C
ESP32-CAN-X2-pinout-diagram
The ESP32-S3 dual CAN bus board is ideal for automotive and industrial applications. Potential projects include creating a button panel to broadcast messages to a Power Distribution Module (PDM), triggering a relay via a CAN bus message, bridging two CAN bus networks with different baud rates, collecting data from two distinct CAN bus networks, isolating traffic between CAN networks, and developing a “man in the middle” agent for CAN bus message source identification and reverse engineering.
The company provides Arduino and CircuitPython examples on GitHub to help users get started quickly with a ping pong example that sends packets between the CAN1 and CAN2 interfaces of the board. More technical details about the hardware and instructions to get started with the Arduino and CircuitPython can be found in the wiki.
Autosport Labs offers the ESP32-CAN-X2 board for $49.95 on their website, providing an accessible and versatile solution for high-performance CAN bus applications.
Raspberry Pi units have long been a playground for tech enthusiasts looking to explore and repurpose old software. The latest breakthrough comes from Matt Evans, who has managed to emulate the iconic Macintosh 128K using a Raspberry Pi Pico. This remarkable achievement allows anyone to run a piece of computing history on hardware that costs only $7.
Key Features of MicroMac
The MicroMac project is a testament to the versatility and affordability of Raspberry Pi units. Here are the key features that make this emulation possible:
VGA Output: Despite the Raspberry Pi Pico’s modest specifications, MicroMac supports VGA output, allowing you to connect it to a monitor and enjoy the classic Macintosh interface.
USB Support: The project includes USB support, enabling you to use modern peripherals like keyboards and mice with the emulated Macintosh 128K.
Read-Only Disk Image: MicroMac comes with a read-only disk image, preserving the integrity of the original software while allowing users to experience it as intended.
Emulating a Macintosh 128K on a Raspberry Pi Pico was no small feat. Matt Evans detailed the challenges and intricacies of the project on his Axio.ms blog. The primary hurdles included adapting the original software to run on Pico’s hardware and ensuring stable performance despite the limited resources.
Raspberry Pi units may not boast the highest computing power, but their compact size and adequate specifications make them ideal for retro computing projects. They provide a unique opportunity to revisit old operating systems and software, offering a nostalgic experience for older users and an educational journey for younger tech enthusiasts.
One of the most significant advantages of using a Raspberry Pi for emulation is the cost. At just $7, the Raspberry Pi Pico provides an incredibly affordable way to explore the Macintosh 128K and other vintage software. This low cost makes the project accessible to a wide audience, from hobbyists and educators to students and retro computing fans.
The Raspberry Pi Pico MicroMac build
The MicroMac project by Matt Evans is a shining example of how modern technology can be used to preserve and explore historical software. By emulating the Macintosh 128K on a Raspberry Pi Pico, Evans has opened up a new world of possibilities for tech enthusiasts. Whether you’re interested in reliving the early days of personal computing or looking for a fun and educational project, MicroMac offers a fascinating glimpse into the past for just $7.
This project highlights the potential of Raspberry Pi units and demonstrates the enduring appeal of classic computing systems. With MicroMac, the Macintosh 128K lives on, providing a tangible connection to the early days of personal computing. Evans offers instructions to build the Pico MicroMac on the Github project page.
He does warn potential builders that a lack of soldering skills could lead to a zapped mouse. Nevertheless, it’s a great use for a Pico and demonstrates just how fast microcontrollers have come.
The TerraMaster F2-212 is a compact 2-bay Network Attached Storage (NAS) device mainly designed for home users. It features a powerful ARM V8.2 quad-core processor,1GB DDR4 RAM, and 4K video hardware decoding making it perfect for streaming high-quality media, a data server, and much more. The F2-212 runs on the intuitive TOS5 operating system, offering an array of features like flexible storage management (TRAID), comprehensive data backup solutions, and seamless file sharing across platforms all these features are just for $169.99 before adding your hard drives. The NAS is designed so that the HDDs can be installed without any tool and with an intuitive interface and easy setup process this device is ideal for everyday use.
Design & Build Quality
This NAS boasts a compact & simple design, making it suitable for home & small office environments. The NAS costs around $169.99 so the build quality is not as great as what we see in more high-end NASs and the body is made out of plastic, which makes the NAS a bit lightweight, and feels a bit less robust. The drive bays are easily accessible for quick swapping, but they lack a locking mechanism found on pricier models, which might be a concern if the device isn’t tucked away. Even though the device is budget-friendly this doesn’t mean that its performance is mid-range and this thanks to the Realtek 1619B processor with its built-in Mali G57 GPU the performance is top-notch. Overall, while not the most visually striking or ruggedly built NAS, the F2-212’s functionality and performance more than make up for its simple and fair design and build.
Storage Capacity and Performance
The NAS can hold two 3.5″ or 2.5″ SATA drives, so you can pick the storage size and type that works best for you. It is an updated version of the previous generation, F2-210 so it men’s it has double the storage capacity of 44 TB, which is enough for most homes & small offices. It runs on a powerful ARM V8.2 Cortex-A55 64-bit 1.7GHz quad-core processor and has 1GB of DDR4 RAM and video DSP hardware acceleration. Additionally, it has 4K video encoding and decoding capabilities making sure it works smoothly for daily use like home documentation & multimedia entertainment.
To test the NAS we installed 2 x Seagate IronWolf 4TB disks as seen in the photos above.
Features and Functionality
Two Drive Bays with TRAID support: TRAID is the abbreviation of TerraMaster RAID. TRAID is a flexible disk array management protocol developed by TerraMaster. It has features such as the automatic combination of disk space, hard disk failure redundancy protection, and automatic capacity expansion. The two-drive NAS protects your data by mirroring the contents of one drive to the other drive because of its RAID 0 & RAID 1 configuration. It also has JDOB & single disk mode, which provide options for data repetition & performance.
TerraMaster OS or TOS 5: The TerraMaster F2-212 NAS runs on TOS 5, TerraMaster’s own operating system. This is an updated version of the previous generation’s OS and boasts over 50 new functions and 600 improvements. The new features do way more business; they’re way faster, safer, and easier to use than before. So basically, it’s like a total upgrade.
Multimedia server capabilities: It has a powerful 4K video hardware decoding capability compatible with the UPnP/DLNA protocol. Plus, it can handle streaming videos and music super well, just like the apps EMBY, PLEX, and iTunes. making it a great choice for multimedia streaming, like movies & music.
File sharing & remote access: It supports all kinds of file services, like SMB, NFS, SFTP/FTP, AFP, iSCSI, and WebDAV, and it has multiple permission settings for users, user groups, and folders, so it can work with different network setups & platforms. It has both EXT$ & Btrfs-supported file systems. It can be accessed through web or mobile apps (IOS or Android).
Security: TerraMaster created the TerraMaster File System Snapshot (TFSS) as a data protection tool. It takes snapshots of the whole file system using the BTRFS file system. This keeps all your data on the TNAS device safe. If something goes wrong, you can easily click on the snapshot list to recover your data quickly, without worrying about mistakes or ransomware attacks.
Multiple Backup Options: It supports time machine backup, TFSS, TFM backup, cloud sync, remote backup, and duplicate backup. So that it can protect valuable data using multiple backup applications.
Mobile Application: The TerraMaster F2-212 is designed for easy access on the go. Its mobile app lets you view files, back up photos, and share them from your phone or tablet. You can even manage the device remotely, making it a flexible storage solution for your digital life.
Advanced Data Protection and Backup: TerraMaster’s TOS 5 offers a robust suite of backup solutions to safeguard your valuable data. From Time Machine for Mac users to TerraMaster’s own snapshot technology (TFSS) and TFM Backup, you can easily create multiple copies of your files in different locations, including the cloud. These features ensure that your data is protected against accidental deletion, hardware failure, or even ransomware attacks, giving you peace of mind.
AI Album Management: Terra Photos uses AI to organize your photos. It can recognize faces and objects, grouping them into albums. It also sorts photos by location, making it easier to find and share your memories.
Expandable Functionality with Docker: The TerraMaster F2-212 NAS unlocks various possibilities with its integrated Docker Manager. This user-friendly tool connects you to Docker Hub, a vast library of containerized applications. With Docker, you can easily add new features and functionality to your NAS, customizing it to suit your specific needs.
User-Friendly Design and Remote Accessibility
Configuration of the TerraMaster F2-212 is easy with its simple TOS interface. You can adjust settings & use features easily, even if you’re not a very technical person. This device supports many apps & services, making it a great device for network storage.
It has a tray for hard drives that you can install or remove easily without tools. It also has a new push-lock design from TerraMaster itself. When you put in a hard drive, it locks automatically, so the drive won’t fall out. It only takes about 10 seconds to install a hard drive, which is a simple & fast system installation. It is convenient if you often switch drives to move data around.
The mobile app user can access the TNAS device anytime, from anywhere, on any iOS or Android device. It is very easy to access files from afar, manage backups, and check the device’s status. It offers various backup options, and it can connect with popular cloud services, making it a strong storage option & improving its flexibility of use.
TerraMaster F2-212 Specifications:
Processor:
Model: Realtek 1619B
Architecture: ARM V8.2 Cortex-A55 64-bit
Frequency: Quad Core 1.7 GHz
Memory:
System Memory: 1 GB DDR4 non-ECC
Pre-installed Memory: 1 GB DDR4 non-ECC
Maximum Supported Memory: 1 GB DDR4 non-ECC
Storage:
Disk Slots: 2
Compatible Drive Types: 3.5″ SATA HDD, 2.5″ SATA HDD, 2.5″ SATA SSD
Maximum Internal Raw Storage Capacity: 44 TB (22 TB x2)
Power Management: Scheduled Power On/Off, Wake up On LAN (WOL), UPS-Supported
Administration: Control Panel, Resource Monitor, Syslog
Application Center: Docker Manager, Multimedia Server (Plex), CloudSync
Backup and Storage Management:
Supported RAID Types: Single, JBOD, RAID 0, RAID 1
Snapshot and Rsync Backup Support
Maximum Internal Volume Number: 64
Environment:
Operating Temperature: 0°C to 40°C
Storage Temperature: -20°C to 60°C
Relative Humidity: 5% to 95% RH
Getting Started
After disk installation, we have to follow the online getting started guide. Following the guide you will install the required operating system and get ready to login to the system in about 10 min. An internet connection is needed so the TOS is downloaded and installed.
After TOS installation you will be able to login to the operating system and finish the configuration. The TOS is an impressive piece of software that will enable you to manage all the things needed for your NAS. Additionally, it loads fast and it’s very responsive.
Performance Testing
To test the performance of the NAS we copied a 4GB file on the drives. You can see the write and read speed of the file on the following screenshots.
copying a a 4GB file from PC to Terramaster NAScopying a a 4GB file from NAS to PC
The same file was used to test our Synology Diskstation DS218+ NAS and compare the performance. As we see on the screen below, the Synology NAS outperforms the TerraMaster in terms of writing speed by ~30MB/s, measured on the same LAN.
copying a a 4GB file from PC to Synology NAS
Conclusions
The TerraMaster F2-212 is a great option for anyone who is looking for a budget-friendly & dependable 2-bay home storage system. It works well for storing files, streaming media, flexible storage management, advanced file service, building a convenient and safe private cloud, flexible mobile access, improved desktop assistance, AI management, and backing up data. It might not have all the modern features or speed of more expensive NAS devices, but it’s a good product with high security for the price & works well for most homes & small offices.
The TerraMaster F2-212 NAS is priced around US$169.99 and can be purchased from TerraMaster’s official store page.
The Elecrow RC101S is a 10.1-inch IPS touchscreen display with 1024×600 resolution. The device is specially designed for a Raspberry Pi as it has additional mounting points for the Pi. Still, it can also be used as an extended display for your workspace that adds up to your productive development.
The RC101S also has an HDMI-compatible, Capacitive Touch Screen, 3.5mm Audio Interface, and Stereo speakers and gets powered from a USB-C port making it usable for a variety of applications. The device’s plug-and-play capacitive USB touchscreen eliminates the need for driver installations. Dual detachable speakers enhance the audio-visual aspect, while four corner holes enable easy mounting on DIY projects. The display also comes with a stand so that you can put it on a tabletop as a standalone device. It is also great for gaming on the go or video or photo editing as it’s an IPS display that produces great color accuracy.
Highlights:
10.1-inch IPS monitor: The 10.1-inch high-definition display has a resolution of 1024×600 and uses an IPS screen to provide an excellent visual experience.
Plug and play: Using capacitive USB touch screen, you only need to supply power to the USB touch port to realize the touch function. There is no need to install a driver, just plug and play.
Dual Speakers: Equipped with dual detachable speakers to enhance your audio-visual experience.
A Compact and Functional Package
The RC101S ships in a neatly organized box, along with all the necessary accessories including the display, the Stereo speakers, HDMI-compatible Cable, HDMI-compatible to HDMI-compatible Adapter, micro HDMI-compatible to HDMI-compatible Adapter, MicroUSB to USB Adapter, MicroUSB to USB Adapter, Copper Posts and Screws, Cross Screwdriver all this makes things easy for to get started with the device.
Package List
1 x 10.1-inch Touchscreen Monitor
2 x Stereo speakers
1 x HDMI-compatible Cable
1 x MicroUSB Cable
1 x HDMI-compatible to HDMI-compatible Adapter
1 x micro HDMI-compatible to HDMI-compatible Adapter
1 x MicroUSB to USB Adapter
1 x MicroUSB to USB Adapter
4 x Copper Posts and Screws(M2.5)
1 x Cross Screwdriver (small)
The display itself is very lightweight, which makes it very easy to carry it around, the build quality is also very robust with an aluminum chasee and the minimalist design makes the device look stunning. Additionally, the display is framed by a sleek black bezel, giving it a modern and understated look.
Display and Touchscreen
The main feature of this device is its 10.1-inch IPS display. While the 1024x600px resolution might not seem that interesting in comparison with the 2K and 4K resolutions that we often find in our monitors, it’s important to remember that this is a compact, portable monitor. It can do everyday tasks like web browsing, document editing, and even light gaming and much more. The one downside is that it has an 800:1 contrast ratio meaning it’s great for indoor conditions but you will have difficulty in outdoor conditions.
However, if you’re using a very high-resolution monitor as your daily driver, you’ll notice the pixelation, especially when viewing text-heavy content or intricate images. That isn’t a dealbreaker for most use cases, but it’s something to keep in mind if you’re a pixel-savvy guy like me. The most interesting feature of this display is its touchscreen, the display is very responsive and accurate making interactions feel natural and intuitive. document scrolling tapping icon drawing will feel very smooth and accurate with it, one thing also mentioned is that the display has multi-finger input so gestures like pinch-to-zoom scroll are also easily possible.
Audio and Connectivity
Another great feature of this display is that it comes with built-in dual speakers. While they won’t rival a dedicated sound system, they are comparable to standard laptop speakers which is great for casual listening
One of the standout features of the RC101S is its built-in dual speakers. While they won’t rival a dedicated sound system, they produce surprisingly clear and loud audio. For casual listening, watching videos, or even participating in video conferences, the speakers are perfectly adequate. The audio quality is a pleasant surprise for a monitor of this size and price point.
The display also features a standard HDMI port that is used for video input and it also has a micro USB port for both power and touch input. This connectivity allows you to connect it to a wide range of devices, including laptops, Raspberry Pi, desktop computers, and even gaming consoles. The inclusion of various adapters in the package ensures compatibility with almost any device you might have.
Real-World Applications
The application of this device is vast as it finds a home in numerous scenarios. As a secondary display for a laptop, it provides additional screen space for multitasking, research, or reference materials. For Raspberry Pi enthusiasts, it serves as an excellent portable display for projects, monitoring, or even as a compact media center.
In creative fields, the display can be used for digital art, photography, video editing, and much more, only imagination is the limit. Its touchscreen also adds to intuitive interaction with creative software, and its compact size makes it easy to take on location for on-the-go editing. In an educational environment, the display can be used as a portable whiteboard, allowing teachers and students to collaborate on projects, presentations, and interactive learning activities.
Elecrow RC101S 10.1 inch IPS Touchscreen Display Specification
Display: 10.1-inch IPS screen
Resolution: 1024 x 600 pixels
Aspect Ratio: 16:9
Brightness: 300 CD/M2
Contrast Ratio: 800:1
Response Time: 200 ms
Touchscreen: Capacitive touch (GT9271 IC)
Active Touch Area: 222.72mm x 125.28mm
Plug and Play: No driver installation required for touch functionality
Audio: Dual 8Ω 2W detachable speakers
Audio Output: 3.5mm audio interface and stereo speakers
Connections:
Power Input: MicroUSB (5V)
Video Input: HDMI-compatible interface
Included Cables: HDMI-compatible Cable, MicroUSB Cable, HDMI-compatible to HDMI-compatible Adapter, micro HDMI-compatible to HDMI-compatible Adapter, MicroUSB to USB Adapter
Build and Dimensions:
Module Size: 236.00 × 145.57 × (16.60 ± 0.2)mm
Weight: 520g (Net), 900g (Gross)
Compatibility:
Supports Raspberry Pi (e.g., Raspberry Pi 4) with specific configuration instructions
Compatible with Windows (Win7/Win8/Win10) and other operating systems
Certifications: CE and ROHS compliant
Longevity: Estimated 3-6 years of product life
If you are planning to mount the display on an enclosed or print a 3D-printed enclosed yourself, the company provided detailed measurements along with wiki and documentation to get started with the display all of which can be found on elecrow’s user manual page.
The RC101S is a great little display that’s perfect for on-the-go use. It’s small, light, and easy to set up, with a responsive touchscreen and decent sound. While the resolution isn’t the highest and the touchscreen is limited, it’s still a great value for the price. If you need a portable touchscreen display, the RC101S is a great option.
If you’re looking for a compact touchscreen monitor for your laptop, Raspberry Pi, creative projects, or educational endeavors, the RC101S is a worthy contender. Its performance, portability, and value for money make it a valuable addition to any tech enthusiast’s toolkit. So, whether you’re a professional on the go, a hobbyist tinkerer, or a student looking for a portable learning tool, the Elecrow RC101S could be the perfect compact touchscreen companion for you.
Elecrow RC101S 10.1 inch 1024 x 600 IPS Capacitive Touch display can be purchased from Elecrow, priced at $76.99. For more information and tinkering visit Elecrow Community.
Electric Field Due To Uniformly Distributed Charges
Let’s consider a configuration of two nonconducting planes that are oppositely charged and placed in parallel to each other at a small distance. Suppose that the positive and negatively charged planes are set up facing each other.
Figure 1 shows part of two infinitely large, nonconducting plane sheets with two uniform distributions of positive and negative charges on one side.
Figure 1: The uniform electric field caused by uniform distributions of positive and negative charges
In this configuration, the lines of electric field E (blue lines) in the space between the planes would be regularly spaced. Note that some of the field lines are not plotted due to the simplicity of the figure.
The electric field E points away from the positively charged plane and toward the negatively charged plane. In this condition, the electric field has the same direction at every point within the field and the field lines are parallel and evenly spaced. This is called a uniform electric field that exists in a region between two oppositely charged planes with a uniform distribution of charges.
If we place a positive test charge at any point near the positively charged sheet, for example at point P, we find that the electrostatic force on the particle is outward and perpendicular to the sheet. Thus, the electric field vectors and the electric field lines must also be outward and perpendicular to the sheet, as shown in Figure 1.
In a uniform field, the field lines are parallel. This indicates that the electric field E is equal for all points at the same distance to the positive plane in the field.
Of course, there is no such thing as an infinitely large sheet in reality. This is just an assumption to say that we are physically measuring the field at points close to the plane relative to the size of the plane and that we are not near an edge.
Electric Potential In A Uniform Field
In the same structure of Figure 1, assume that a positive test charge q0 is placed at point A in a uniform electric field E, as shown in Figure 2. When this point charge is placed in such an electric field, we can predict it has a movement based on the electrostatic force F applied. Figure 2 shows that if a positive point charge q0 begins at rest in this rightward-pointing electric field, the point charge will move toward the right. If that point charge q0 is instead negative, the point charge will begin to move to the left, against the direction of the electric field.
Figure 2: The displacement of the positive charge q0 between points A and B in a uniform electric field
Essentially, the electrostatic force F is conservative, which means that the work done on q0 is independent of the path taken. The work done by a conservative force depends only on the beginning and ending positions of the object. So, it is possible to define a potential energy associated with the force. The work done by a conservative force can be reinterpreted as the negative of the change in potential energy associated with that force.
In our case the force moves the positive charge q0 farther from the positive plane, and the electric potential energy of the charge q0 decreases. Because it moves from the positively charged plane with a higher level of potential energy (High PE) to the negatively-charged plane with a lower level of potential energy (Low PE).
As the charge moves from point A to point B under the influence of the electric field E, the work done on the charge by the electric field, WAB, is equal to the electric force F times the displacement d, in the same direction. Equation 1 calculates the physical work.
Equation 1: The work done on the charge by the electric field E
As we have already seen in the previous article, the electric potential difference ΔV between points A and B is the change in electric potential energy as a charge q0 moves from A to B divided by the charge q0. Equivalently, it can be defined by the work done on the charge q0 by the electric field.
Then, the potential difference ΔV between two points A and B in the uniform electric field is given by Equation 2.
Equation 2: The relationship between electric potentials, the electric field, and the displacement
Where E is the electric field vector and d is the displacement vector from point A to point B. In such a configuration, because vectors E, F, and d have the same direction, The dot products F.d and E.d give the scalar results, i.e., only magnitudes.
The negative sign Equation 2 indicates that the electric potential decreases in the direction of the electric field. This means that moving in the direction of the electric field corresponds to moving to a region of lower potential. Since the electric field is uniform, the rate of change of the potential concerning distance is constant. However, the work done on the test charge by the electric field is positive when it moves from higher to lower potential.
The familiar term voltage is the common name for electric potential difference. Whenever a voltage is quoted, it is understood to be the potential difference between two points. We have already mentioned that the SI unit of electric potential is ‘joules per coulomb’ or volts (V).
In a uniform field because of parallel and equal electric field vectors, the equipotential surfaces (which are orthogonal to the field lines) are equally spaced parallel to charged planes.
In Figure 3, the equipotential surfaces are plotted as parallel dotted lines for some equal distances between charged planes. Every line (surface) is assigned to an electric potential or voltage, as V1 to V9, i.e., different voltages in terms of different distances to the source of potential energy (High PE).
Figure 3: Equipotential surfaces in a uniform electric field
If we combine the results of Equation 1 and Equation 2, we find Equation 3:
Equation 3: The relation of the work done on the charge and electric potentials
Using this equation, we obtain the following general result: No energy is required to move a charge between two points that are at the same electric potential, like the path AB in Figure 3. Since ‘equipotential’ means that VB = VA and therefore, WAB = 0.
Work is done only when the object moves between equipotential surfaces, for example, the path AG in Figure 3.
Electric Potentials In Charged Conductors
A conductor can conduct, or convey, an electric charge. Metals such as copper, brass, aluminum, and silver are examples of conductors. A property of metal bodies is that they are good conductors of electricity and they readily permit a current flow or motion of charge in them.
If a conductor body is charged, the charges move in conductors until they reach an equilibrium configuration. Essentially, when a conductor is in electrostatic equilibrium, a net charge placed on it resides entirely on its outer surface. The charge in the conductor is distributed on the surface due to the electrostatic force of repulsion. The net charge inside the conductor is zero.
In static situations, a conductor may be defined as a medium in which the electric field is always zero. In this case, the electrostatic field at the surface of a charged conductor has always a direction normal to the surface. Therefore, if a conductor body is charged, the electric potential at all points on a charged conductor is the same. Thus, all of its outer surface can be considered as an equipotential surface.
Figure 4 shows a metal sphere with a radius R that is positively charged. We can consider the magnitudes of the electric field E and the electric potential V inside and outside of its body.
Figure 4: The electric field and the electric potential due to a metal sphere
Recall that for such charged bodies we can find E and V by Equation 4:
Equation 4: The magnitudes of the field and the electric potential
Where ‘r’ is the distance to the center of the sphere and ke = 8.9875 × 109 (Nm2/C2) is the Coulomb’s constant. The units of E, V, and r are (N/C), (volts), and (meters), respectively.
Clearly, inside the conductor (r < R) the electric field is zero and the electric potential has its maximum value (Vm). On the surface of the sphere, both E and V have their maximum values, and by increasing the distance (r > R), both E and V decrease in terms of 1/r2 and 1/r respectively.
Capacitance
If the configuration of the uniform electric field in Figure 1 is reconstructed using two conducting plates, we typically design a capacitor. A capacitor is an electrical device consisting of two conductors separated by an insulating or dielectric medium. Capacitors, with different configurations, are used in a variety of electric and electronic circuits, such as tuning the frequency of radio receivers, eliminating sparking in automobile ignition systems or storing short-term energy for rapid release in electronic flash units.
Figure 5 shows a parallel-plate capacitor consisting of two flat metal sheets separated by distance d.
Figure 5: a parallel-plate capacitor with a uniform electric field
To transfer and hold charges on the plates and produce a uniform field structure, the plates are connected to the positive and negative terminals of a battery as a voltage source. The potential difference or the voltage drop between the positive and negative electrodes of the battery equals Vs. In this simple circuit, all the connections, including capacitor leads and wires, are made of conducting materials.
When the connections are made, electrons are pulled off one of the plates, leaving it with a charge of +Q, and are transferred through the battery to the other plate, leaving it with a charge of -Q, as shown in Figure 5. The transfer of charge stops when the potential difference across the plates equals the potential difference of the battery. Now, this charged capacitor is a device that stores energy, which can be reclaimed when needed for a specific application.
The capacitanceC of a capacitor is defined as the ratio of the magnitude of the charge Q on either conductor (plate) to the magnitude of the potential difference ∆V between the conductors (plates), as explained in Equation 5:
Equation 5: Definition of the capacitance
The SI unit of capacitance is Farad (F), which is equal to Coulomb per volts (C/V). In other words, a capacitor that can store 1 Coulomb of charge with a potential difference of 1 Volt has a capacitance of 1 Farad. Since a capacitor of 1 Farad capacitance is much larger than what is ordinarily used in practice, microfarads (µF) and picofarads (pF) are commonly used units.
Potential Differences In Batteries
Batteries store energy in chemicals and use that energy via specific electrochemical reactions to distribute charges and create an electric field, similar to capacitors.
The traditional lead–acid battery is a type of rechargeable battery. Figure 6 shows the basic lead-acid cell which uses lead plates for the two electrodes, the positive and the negative ones. The container of the lead-acid battery can be made of glass. The electrolyte (sulfuric acid solution) creates a relatively uniform electric field between the electrodes when the battery is charged. The nominal voltage of a lead-acid cell (about 2.1V) represents the potential difference across this field.
Figure 6: The structure of a lead-acid battery cell
A familiar application of potential difference is the 12-volt battery utilized in automobiles. These types of battery sets contain several lead-acid cells (each with about 2.1 V potential differences) in a serial structure. The battery provides the electrical current necessary to operate motors, headlights, radio sets, power windows, and so forth. Such a battery maintains a potential difference across its terminals, with the positive terminal +12 V higher in potential than the negative terminal. In practice, the negative terminal is usually connected to the metal body of the car, which can be considered to be at a potential of zero (virtual grounding).
Figure 7 shows a simple electric circuit containing a 12-volt battery as the source of electric energy, a lamp as the consuming device, and some connecting wires. Now consider a charge of +1 C, to be moved around the circuit that contains the battery connected to the lamp.
Figure 7: A simple circuit of a 12 V battery, a lamp and connecting wires
According to Equation 4, every coulomb of positive charge that leaves the positive terminal of the battery carries an energy of 12 J. As the charge moves through the external circuit toward the negative terminal, it gives up its 12 J of electrical energy to the external device. When the charge reaches the negative terminal, its electrical energy becomes zero. At this point, the battery takes over and restores 12 J of energy to the charge as it is moved from the negative to the positive terminal inside the battery, enabling it to make another transfer around the circuit.
Based on the mechanism of the battery operation, as the charge is moved inside the battery from the negative terminal (at 0 V) to the positive terminal (at 12 V), the work done on the charge by the battery is 12 J.
Conclusions
Understanding the electric potential is crucial for solving many practical problems in electromagnetism, such as those involving parallel plate capacitors or the behavior of charges in uniform fields. It also helps describe how charges interact within electric fields and how energy is stored and transferred in electrical systems.
Summary
If an electric field has the same direction everywhere in a particular space, it is said to be uniform.
In a uniform field, the field lines are parallel.
The amount of work per unit charge is equal to the force per unit charge (or field intensity E) times the distance through which the charge is moved.
The electric potential difference is the work per unit charge that would have to be done by some electric force to move a charge from point A to point B in a uniform electric field.
Electric potential is a scalar quantity.
Voltage is another term for electric potential, it measures the difference in electric potential between two points.
The SI unit of electric potential is the joule per coulomb (J/C), called the volt (V).
A surface on which all points are at the same potential is called an equipotential surface.
Equipotential surfaces are always perpendicular to electric field lines.
When a particle moves from one point to another point on an equipotential surface, the net electric force does not work and ΔV equals zero there.
The charges on a conductor are assumed to be in equilibrium with each other, so none are moving.
the electric field just outside the surface of a charged conductor in electrostatic equilibrium is perpendicular to the surface and the field inside the conductor is zero.
All points on the surface of a charged conductor in electrostatic equilibrium are at the same potential.
A simple capacitor consists of two parallel metal plates separated by a distance d.
A lead-acid battery uses 2 lead plates (connected to the positive and the negative terminals) inside an electrolyte for the conversion of chemical energy into electrical power.
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