SB Components StackyFi is an ESP32-S3 powered development board in a Raspberry Pi Zero Form Factor. The board features a 40-pin GPIO header which is compatible with most Raspberry Pi HAT. The board also has dual USB-C ports (one native, one for serial debugging), an IMU sensor, an RGB LED, and Boot/Reset buttons. The board also features a LiPo battery and can also be charged and powered through that USB. All these features make this device useful for smart homes, security systems, and much more.
Processor: ESP32-S3 WROOM 1, dual-core 32-bit LX7 up to 240 MHz
Memory:
384 KB ROM
512 KB SRAM
Up to 16 MB Flash
Up to 8 MB PSRAM
Sensor: QMI8658C 6D MEMS IMU (accelerometer and gyroscope)
Wireless Connectivity:
2.4 GHz Wi-Fi (802.11 b/g/n)
Bluetooth® 5 (LE)
Compatibility:
Supports most Raspberry Pi HATs
Mirrors Raspberry Pi pin functionality
Interfaces:
40-pin GPIO header
2x USB Type-C ports (1x OTG, 1x serial)
MicroSD card slot
FPC connector for OV2640 camera module
2-pin LiPo battery connector
Other Features:
Programmable WS2812B RGB LED
Boot and Reset buttons
Programming:
Arduino IDE
MicroPython
CircuitPython
Power: 5V DC via USB or LiPo battery
Dimensions: 65 x 30 mm (Raspberry Pi Zero form factor)
Video
SB Components claims the StackyFi board is open-source and supports Arduino IDE, MicroPython, and CircuitPython. However, when it comes to documentation there are many key aspects they are missing. The documentation lacks key technical details like memory capacity, and the company also provides schematics which are also very unclear. While they claim Raspberry Pi HAT compatibility, the company does not provide any evidence of that. More information is expected on GitHub after the crowdfunding campaign.
High Torque Robotics Miniπ is a 54cm tall bipedal robot built around the Orange Pi 5 SBC with Rockchip RK3588S for better performance and control. The robot has 12 degrees of freedom(DOF) with 12 custom joint motors, allowing it to walk, dance, run, jump, and flip. Designed for research and education, it supports advanced algorithms like ZMP(zero moment point), MPC(Model Predictive Control), reinforcement learning, and ROS SLAM for navigation.
In our previous post, we wrote about Amy Robots which is an innovative technology company focusing on research and development of service robots that enhance quality of life with robotic technologies, products, and services. Feel free to check this out if you are interested in this product.
High Torque Robotics said the Mini π comes with a robot test stand and trolley case. For more details, visit the Hackster.io project page. There, you can find the schematic, locomotion control algorithm code, and more information about the joint motors. High Torque Robotics says the robot is open-source, and the algorithm is simulated and verified on the 12 DOF Mini π. The open-source code is available on GitHub.
High Torque’s official page offers three distinct Mini π robot configurations. The “Basic Configuration of Motion Control Board” is available in two options, priced at $7,600.00 and $8,711.00 respectively. For those seeking advanced capabilities, the “Perception Version Configuration (Orin + Main Control + IMU)” comes equipped with additional features and is priced at $11,950.00.
Khadas has introduced the Mind Graphics eGPU, which features the NVIDIA GeForce NVIDIA Ti. This external GPU enhances performance for creative design, video rendering, and gaming. Key features include DLSS3 technology for smoother frame rates, AV1 encoding for better video compression, and support for up to four screens through various ports including Thunderbolt 4/3 USB-C, HDMI 2.1a, and DisplayPort 1.4a. The eGPU is a versatile hub with a built-in microphone array, dual-driver speaker system, and 85W PD fast charging. Housed in a 2.5L Al-Si-Cu die-cast aluminum alloy chassis this can be used for applications like Creative Design, Gaming, Video Rendering, and much more.
Previously we have written about ADT-Link UT3G a USB4 to PCIe x16 eGPU adapter, which is a GPU adapter that costs only $129.0 and can hold an RTX4090, feel free to check that out if you are looking for something cheap and useful.
Khadas Mind Graphics eGPU Specifications
Processor and GPU:
NVIDIA GeForce RTX 4060 Ti Desktop GPU (8GB GDDR6)
Mind Link Max Speed: 128 GT/s
Memory and Storage:
Not specified
Display and Graphics:
2× HDMI 2.1a (Supports 4K/240Hz or 8K/60Hz)
1× DisplayPort 1.4a (Supports 4K/240Hz or 8K/60Hz)
Audio:
Built-in dual speaker system for an immersive audio experience
The Mind Graphics eGPU Module integrates a microphone array, dual-driver speaker system, and 85W PD fast charging, streamlining setup by combining GPU performance and device charging into one solution. Khadas emphasizes the 2.5L chassis made from Al-Si-Cu die-cast aluminum alloy, offering durability and a premium look.
Khadas Mind Graphics eGPU costs only $999 and is available on Khadas shop now, you can also purchase it from Amazon from August 1st. Includes everything you need.
Orange Pi has introduced a new single-board computer called the OrangePi 5 Max. It is powered by the octa-core Rockchip RK3588 and features a 2.5GbE LAN port and an M.2 M-Key slot. It also includes LPDDR5 RAM, eMMC, microSD, and M.2 storage options. Additionally, it has Wi-Fi 6E + BT 5.3/BLE, dual HDMI 2.1 outputs, multiple camera interfaces, USB 3.0 and 2.0 ports, and a 40-pin GPIO expansion port. It supports various operating systems, including OrangePi OS, Ubuntu, Debian, and Android 12.
Configurable UART, PWM, I2C, SPI, CAN, GPIO, and other functional interfaces
Buttons:
1x BOOT key
1x On/Off key
Power Source: Supports Type-C power supply, 5V @ 5A
LED: RGB LED Side Illumination
Fan: 5V 2PIN 1.25mm socket
RTC: 3V 2PIN 1.25mm socket
Debugging: Debug serial UART included in 40PIN expansion port
Supported OS:
Orangepi OS (Droid), Orangepi OS (Arch),Orangepi OS (OH),Ubuntu,Debian, Android 12
Dimensions:
PCB Length: 89mm
PCB Width: 57mm
PCB Thickness: 1.6mm
Weight: 62g
The OrangePi 5 Max supports multiple operating systems, including OrangePi OS (Droid, Arch, OH), Ubuntu, Debian, Android 12 and much more information about that can be found on their wiki page. Additionally, you can check out their products page for more information.
The Orange Pi 5 Max is priced at $95 for the 8GB RAM model and $125 for the 16GB RAM model, according to Orange Pi’s X account. The 4GB model, while mentioned, is not currently listed on their AliExpress page.
Artificial Intelligence (AI) has transformed various industries, offering transformative solutions that enhance efficiency, accuracy, and decision-making processes. iWave enables innovation at the edge with embedded platforms enhancing innovation at the edge for Artificial intelligence, Media processing, Robotics and visual computing.
iWave is excited to launch iW-RainboW-G58M, powered by the Intel Agilex 5, which is the first FPGA with AI infused into the fabric. The SoM is built for applications in fields such as medical, robotics, and industry that need efficient, high-performance custom logic with AI/ML hardware support.
The System on Module (SoM) is built in a compact form factor of 60mm x 70mm and is compatible with the Intel Agilex® 5 FPGA and SoC E-Series family and B32A package in two device variants:
Group A: A5E 065A/052A/043A/028A/013A SoC FPGA
Group B: A5E 065B/052B/043B/028B/013B/008B SoC FPGA
Intel Agilex® 5 FPGAs and SoCs enhanced the industry’s first AI tensor block from Intel’s previous AI-optimized FPGA for general purpose, mid-range FPGAs in Intel Agilex® 5 FPGAs, making them an ideal choice for edge AI applications. The Agilex® 5 FPGA features an asymmetric applications processor system consisting of dual Arm Cortex-A76 cores and dual Cortex-A55 cores that optimize the performance and power efficiency of their workloads. Integrated with an enhanced DSP with AI Tensor block, the Agilex 5 offers advanced connectivity features such as High-speed GTS transceivers up to 28.1 Gbps and PCI Express ( PCIe ) 4.0 × 8, DisplayPort and HDMI Output.
The AI/ML software capabilities start with popular platforms such as TensorFlow and PyTorch, including the support for the open-source OpenVINO toolkit that works with the FPGA AI Suite and Quartus Prime FPGA design software. The OpenVINO toolkit takes Deep Learning models from all the major Deep Learning frameworks (such as TensorFlow, PyTorch, Keras) and optimizes them for inference on a variety of hardware architectures, including various CPUs, CPU+GPU, and FPGAs. The Intel FPGA AI Suite was developed with the vision of ease-of-use of artificial intelligence (AI) inference on Intel FPGAs.
The suite enables FPGA designers, machine learning engineers, and software developers to create optimized FPGA AI platforms efficiently. Utilities in the Intel FPGA AI Suite speed up FPGA development for AI inference using familiar and popular industry frameworks such as TensorFlow or PyTorch and OpenVINO toolkit, while also leveraging robust and proven FPGA development flows with the Intel Quartus Prime Software.
iWave is now shipping early samples of the Agilex® 5 System on Module and evaluation kit, which comes with complete user documentation, software drivers, and a board support package. iWave provides their customers with an evaluation kit with the latest software packages to expedite their evaluation and time to market. Click here for watch the video on the System on Module and Evaluation Kit.
Cloud AI & Edge AI
Edge AI devices can process data, make decisions independently, operate with minimal latency, and derive valuable insights even in absence of network connectivity. Cloud AI processes data in remote data centers with high scalability but higher latency and security concerns, while Edge AI processes data locally on devices with lower latency and improved privacy.
This system consist of the edge node’s main function is to collect data from clients and perform intensive processing tasks where the devices can process data, independently make decisions, offer virtually no latency, and generate valuable insights when internet connections are down. And the data center can consolidate data from several edge nodes to utilize it in more sophisticated applications. This process not only helps in data privacy but offers low latency and covers the large bandwidth.
iWave maintains a product longevity program that ensures the System on Modules are available for long periods of time (10+ years). iWave offers customers extensive technical support during the evaluation and product development phase, alongside ODM Design services such as carrier card design, thermal simulation, and ODM as a business model.
iWave is an embedded systems engineering and solutions company, designing solutions for the Industrial, Medical, Automotive, and Avionics vertical markets. Building on a core competency of embedded System on Modules and embedded computing platforms enabling customers in their product development journey. Learn expertise since 1999, iWave boasts of an extensive portfolio of high-performance FPGA and SoC FPGA more about iWave at www.iwavesystems.com.
ASRock Industrial, a world-leading innovator for Industrial PC and embedded computing solutions, launches DSF-A6000 Embedded Box PC, a cutting-edge display signage solution designed to meet high demands of modern business environments. By leveraging the power of AMD Ryzen™ Embedded R2314, this solution ensures top-tier processing power and graphics performance, supporting 4K quad displays for vibrant, crystal-clear visuals. This advanced product integrates Out-Of-Band-Management (OOBM) and EDID Emulation to ensure seamless operation and enhanced manageability. The DSF-A6000 is meticulously crafted to provide exceptional performance, reliability, and versatility, making it an ideal choice for a wide range of embedded and modern business applications, including digital signage, video walls, and kiosks in smart retail, smart transportation, and smart city settings.
Key Features of the DSF-A6000
Powered by AMD Ryzen™ Embedded R-Series (R2314) with longevity support.
Dual-channel ECC/non-ECC SO-DIMM DDR4 2666 MHz, up to 64GB. Storage options include one M.2 Key M (2242/2280) with PCIe Gen3 x4 for SSD.
Supports quad displays up to 4K resolution with HDMI 2.0b, delivering sharp, vibrant visuals for enhanced operational efficiency and user experience.
Triple RJ-45 ports support two 1G LANs and one 2.5G LAN with PoE+ (optional) for reliable connections.
Multiple IO and expansion options including two USB 3.2 Gen2, one USB 2.0, one COM port, one M.2 Key B, and one M.2 Key E for flexible integration with various devices and systems.
Optional support allows AIIxon 24/7 to perform remote management and troubleshooting regardless of the operating system state through MPU-OOB card.
Emulate the Extended Display Identification Data (EDID) of various displays for compatibility and optimal configuration settings.
Compact design of 182.2 x 175.2 x 25mm makes it easy to integrate into embedded solutions while saving space.
Seamless Remote Management with Advanced Out-Of-Band Management (Optional)
The DSF-A6000 with MPU-OOB card, integrated with Allxon’s Cloud-Native platform, provides advanced OOBM capabilities to empower IT/OT administrators to perform remote management and troubleshooting regardless of the operating system state. This feature is critical for maintaining system uptime and minimizing operational disruptions, enabling remote diagnostics and issue resolution even when the primary network is down. By leveraging OOBM technology, businesses can maintain optimal performance and address issues swiftly, ensuring smooth operations.
Enhanced Compatibility with EDID Emulation
To further enhance its versatility, the DSF-A6000 includes EDID Emulation, which allows the device to emulate the Extended Display Identification Data (EDID) of various displays. This ensures compatibility and optimal configuration settings, simplifying the setup process and providing greater flexibility for diverse display environments.
ASRock Industrial’s DSF-A6000 sets a new standard in display technology, offering businesses a high-performance, reliable solution that meets the demands of today’s dynamic operational needs. With its comprehensive feature set, including OOBM and EDID Emulation, the DSF-A6000 is poised to become an essential tool for boosting business efficiency and productivity.
IBASE Technology Inc. , unveils the IB962 3.5-inch single board computer (SBC) built on the advanced Intel® Core™ Ultra 7/5 100 Series processors (formerly Meteor Lake U/H). Featuring 3D performance hybrid architecture, advanced AI capabilities, and available with built-in Intel Arc™ GPU, the processor delivers an optimal balance of performance and power efficiency and helps unlock the power of AI to create immersive graphics experiences.
The IB962 is available in a variety of models, with high-end models powered by the Intel® Core™ Ultra 7-165H and Ultra 7-165U processors to meet different processing needs while maintaining a compact footprint of just 102mm x 147mm (4″ x 5.8″). The IB962 series comprises two DDR5 SO-DIMM slots, supporting up to 64GB of RAM to handle intensive multitasking and high-speed data processing with ease. A standout feature is its extensive display capability, supporting HDMI, DP++, LVDS, and eDP interfaces, allowing flexibility to connect multiple high-resolution displays simultaneously, whether for industrial automation, manufacturing, retail, entertainment, healthcare, or other edge AI applications.
IB962 FEATURES:
Onboard Intel® Core™ Ultra 7/5 100 Series processors
2x DDR5 SO-DIMM, Max. 64GB
Supports HDMI, DP++, LVDS and eDP
1x Intel® I226LM 2.5G LAN, 1x Intel® I226V 2.5G LAN
3x USB 3.2, 3x USB 2.0, 2x COM, 2x SATA III
3x M.2 slots (M-Key + E-Key + B-Key)
Supports 5G, digital I/O (4-in/4-out), TPM & watchdog timer
The robust IB962 SBC features high-speed networking connectivity with dual Intel® 2.5G LAN ports and a comprehensive array of I/O options such as USB 3.2, USB 2.0, serial port, and SATA III. It also includes M.2 slots (M-Key, E-Key, B-Key) that support additional storage, wireless modules, 5G connections, and other expansions. Its versatile 12V to 24V DC input range ensures compatibility with a variety of power sources and environments.
AAEON’s new ACP-1075 and ACP-1078 offer easily integrated and managed compact solutions for industrial and retail needs.
Leading industrial PC provider AAEON has announced the release of two new All-in-One Panel PCs, the ACP-1075 and ACP-1078. Both new releases feature 7” WSVGA projected capacitive touch screens and compact, fanless chassis designs. Their distinct attributes indicate that AAEON has tailored them for specific markets.
The ACP-1078 is certainly the more versatile and rugged of AAEON’s new offerings, boasting an IP65-compliant aluminum front bezel, broad 12V to 24V power input tolerance, and both VESA and panel mounting options. As such, AAEON has earmarked the product for deployment in industrial settings, with data collection and monitoring in manufacturing and inventory management in logistics being key target uses.
The ACP-1078 is powered by the Rockchip™RK3568 Quad-Core Arm® Cortex®-A55 processor and can support both Android™ 12 and Debian operating systems. Compared to previous generations of AAEON Panel PCs, the ACP-1078 stands out with up to 4GB of LPDDR4 system memory and a much denser range of interfaces. Among these are dual RJ-45 ports for Gigabit Ethernet, two COM ports (RS-232/422/485 x 1, RS-232 x 1), and two USB 3.2 Gen 1 ports, with one USB Type-C OTG for system recovery.
With AAEON marketing the solution for industrial environments, the inclusion of both HDMI display and audio output makes it well-suited for deployment in human-machine interface (HMI) applications. For expansion, the system offers a full-size mini-PCIe slot for either PCIe Gen 3 or SATA, along with a micro SD card to complement 16GB of onboard eMMC system storage.
AAEON’s second Panel PC offering, the ACP-1075, is aimed at customers who need a cost-effective, compact open-frame solution that can be easily installed in applications like smart kiosks. It comes with either the Intel® Pentium® Processor N4200 or an Intel® Celeron® Processor N3350, and runs on a 64-bit Windows OS. The ACP-1075 is designed to be efficient in deployment and operation.
Despite its compact 7.18” x 4.73” x 2.09” size, the ACP-1075 offers strong storage and expansion options. It comes with 64GB of onboard eMMC, along with both M.2 2280 B-Key and M.2 2230 E-Key slots, providing support for SSDs and Wi-Fi modules for multimedia content and wireless connectivity. These features are useful for remote updates and monitoring.
Onboard interfaces include three USB ports (two USB 3.2 Gen 1 and one USB 2.0), one RJ-45 port for Gigabit Ethernet, and two DB-9 ports offering RS-232 for cost-effective, reliable, and straightforward serial communication. Crucially, there is also an HDMI display port to complement the system’s multi-touch touchscreen.
For detailed specifications and more information about the ACP-1075 and ACP-1078, please visit https://www.aaeon.com/en/ or contact your AAEON representative via AAEON’s dedicated contact form.
This simple circuit illuminates an LED or bulb using a ripple counter in a specific order at a predefined interval.
Electronics enthusiasts and students often like building different circuits for their home or school projects, particularly those that flash a few lights. One incredibly flexible integrated circuit (IC) that may be used to create a straightforward LED flasher circuit is known as a binary ripple counter. Several circuits and kits in the market can flash any number of LEDs or lights intermittently, randomly, or consecutively.
As we have discussed in the Counters’ lesson, ripple counters are toggle flip-flops that we can utilize in our basic LED flasher design to act as frequency dividers, dividing the reference clock input by a particular period to produce a new, lower-frequency signal.
Since not every flip-flop in these counters’ “toggles” in unison when an external clock pulse is applied, these counters are termed asynchronous. Typically, the toggling takes place on the clock pulse’s negative edge.
The fundamental feature of all counters is the toggle, also known as a “T-type” flip-flop. Asynchronous counters are also known as “Ripple counters,” because the input clock pulse appears to “Ripple” through the counter when the clock input for one stage is generated from the output of the preceding stage. When each step changes sequentially, the outcome is a ripple effect, which may be effectively used to create a basic LED Flasher circuit.
Ripple counters comprise a series of divide-by-2 T-type flip-flops cascaded together to produce a single divide-by-N frequency divider, where N equals the counter’s bit count. The 74LS93 4-bit (÷16), CMOS 4024 7-bit (÷128), CMOS 4040 12-bit (÷4096), and the bigger CMOS 4060 14-bit (÷16,384) counter are examples of commonly available binary ripple counter integrated circuits.
The “Nth” step of the counter would then be defined as their output count (Qn). Thus, for instance, output Q6 is 26 = 64 (1/64 of the clock frequency), Q12 is 212 = 4096 (1/4096 of the clock frequency), and so on.
The CMOS CD4040B 12-bit Binary Counter is a very versatile integrated circuit that can be used to create a basic LED flasher for use in a variety of different lighting displays. As we’ve seen, there are many binary counters available that can flash any number of lights periodically, randomly, or sequentially.
The CD4040B is a 12-bit binary ripple counter that switches quickly and has twelve completely decoded outputs, or a total of twelve different LED sequences. As each clock pulse’s negative edge approaches, these twelve outputs successively switch, creating the binary output sequence seen in the timing diagram.
For a lights project, the 4040 is perfect as a simple LED flasher or lighting display since its outputs alternate between a logic “1” or “HIGH” and a logic “0” or “LOW” on each count, allowing it to create a moving sequence, chaser, or random effect.
Given that the 4040 is a 12-bit ripple counter, the timing diagram that follows illustrates how each of the twelve outputs will alternate between HIGH and LOW in a binary sequence ranging from 0 to 4096 (212).
4040 Ripple Counter Timing Diagram
Fig-1: 4040 Ripple Counter Timing Diagram
To include the 4040B ripple counter into our basic LED Flasher circuit, we must first generate a timing signal. A timing or clock signal can be produced in many ways—the possibilities are virtually limitless. However, utilizing a specialized timing integrated circuit (IC) like the NE555 Astable Timer is a very easy and efficient approach to producing a square wave timing signal with the fewest possible components.
The selected input clock frequency determines the timing period T, where T = 1/ƒ. Therefore, our input clock frequency on pin 10 of the 4040 counter would need to be approximately 1kHz, (0.25 x 4096), as shown, if we decide to use the 4040 12-bit (÷4096) counter as part of our simple LED flasher circuit and we want our longest timing period on the 12th-bit to be 4 seconds (2 seconds ON and 2 seconds OFF), or 0.25Hz.
Simple LED Flasher Circuit
Fig-2: LED Flasher Circuit
Our simple LED flasher circuit will work best if the LEDs are connected with different outputs since they will flash one at a time, but at separate rates from one another (each output is half the frequency of the preceding one), and they won’t all be “ON” or all “OFF” at the same time.
Depending on which ripple output you connect the LEDs to and how you physically arrange them, you can create any kind of LED flashing light display or a twinkling star effect by using divide-by-2 frequency dividers/counters and multiple LEDs connected to their outputs.
Ripple Counter Output
The outputs of the counters, Q1 through Q12, may either “Source” or “Sink” a load current up to a maximum of around 15mA, which is sufficient for operating the LEDs directly.
Because the 4040 counters can “source” (supply) as well as “sink” (absorb) current, LEDs can be connected between the counter’s output terminal and ground to source load current, or between the counter’s output terminal and supply to sink load current. The illustration for the Sourcing and Sinking is shown in the figure below.
Sinking and Sourcing the Outputs
Fig-3: Sinking and Sourcing
The LED in the first circuit above is linked to the output, in this instance Q8, and the positive supply (+Vcc). This indicates that when the output is “LOW,” the current will “sink” (absorb) or flow into the 4040 counters’ output line, turning on the LED.
The LED is linked between the output, Q8, and ground (0 volts), as the second circuit above demonstrates. This indicates that when the output is “HIGH,” the LED will be “ON” and the current will “Source” (supply) or flow out of the 4040 counters output port.
We can utilize more LEDs in our simple LED flasher circuit because the ripple counter can source and sink its output load current, allowing both LEDs to be connected to a single output terminal. Only one LED will, however, be turned “ON” at any one moment based on whether the output state is “HIGH” or “LOW.”
Fig-4: Dual LED with Sink and Source
An example of this is shown in the above-shown circuit. Depending on the output, the two LEDs will alternately be turned “ON” and “OFF,” producing an alternating flashing movement. If necessary, series resistors can be added to lower the LED current to less than 15mA.
As we mentioned earlier, the output pins may sink or source the load current up to a maximum of 15 mA, which is more than sufficient to drive or switch LEDs, tiny lights, and other similar devices. However, what if we wished to use this simple LED flasher in place of switching or controlling higher-power equipment like motors, electromagnets, or relays? Then, to supply an adequate current to drive the load, transistors would be required.
Ripple Counter Transistor Driver
Fig-5: Ripple Counter Transistor Driver
If the load current is high, the transistor in the first two cases can be swapped out for a Power MOSFET or a Darlington transistor. It is best to connect a “freewheeling diode” straight across the load terminals of an inductive load, such as a motor, relay, or electromagnet, to absorb any back EMF voltages produced by the inductive device as it changes state.
More LEDs may be added to the output, but they typically need 15 to 20mA at 1.2V to properly glow, when the circuit is connected to a battery or power source. The 4040 IC has the benefit of self-limiting its maximum input/output current, which allows LEDs to be connected directly without the use of current-limiting resistors.
Conclusion
A simple LED Flasher circuit can be constructed using a binary ripple counter. A binary ripple counter, an integrated circuit (IC), is ideal for this purpose due to its ability to divide frequencies and create sequential outputs.
Several binary ripple counter ICs are available, such as the 74LS93, CMOS 4024, CMOS 4040, and CMOS 4060, each offering different division capabilities. The CD4040B, a 12-bit binary ripple counter, is highlighted for its versatility in creating LED flashers. It can generate twelve distinct LED sequences, switching outputs with each negative edge of the clock pulse.
To generate the necessary clock signal for the CD4040B, an NE555 Astable Timer IC is suggested. The timer can produce a square wave timing signal with minimal components. By adjusting the input clock frequency, different flashing rates can be achieved. For example, a 1kHz clock frequency will create a 4-second on/off cycle on the 12th-bit output.
Transistors or MOSFETs are used to switch higher-power loads, such as motors or relays if needed. Freewheeling diodes are recommended across inductive loads to absorb back-EMF voltages. Additional LEDs can be connected to the outputs, and the 4040 IC’s current-limiting feature allows direct connection without resistors.
Sipeed Lichee Book 4A is a RISC-V lightweight laptop featuring a 14-inch 1920×1200 display, RISC-V TH1520 SOM (8+32/16+128 options), and various connectivity options including USB-A, USB-C, SSD slot, and more. It is designed for RISC-V developers to explore real-life applications of RISC-V technology.
The TH1520 is born out of the Wujian 600 platform unveiled by Alibaba in August 2022 and is capable of running desktop-level applications such as Firefox browser and LibreOffice office suite on OpenAnolis open-source Linux-based operating system launched by Alibaba in 2020.
In our previous post, we also wrote about the Lichee Console 4A, a compact laptop powered by a Lichee Pi 4A RISC-V processor. It has 16GB of RAM, multiple storage options, and built-in Wi-Fi. Feel free to check this out if you are looking for similar products.
The Book supports M.2 2280 SATA SSDs, which can be installed by removing the SSD cover on the back. If you do not plan to use an SSD, you can manually turn off the USB-to-SSD chip to reduce power consumption (about 0.6 watts) and extend battery life.
Sipeed Lichee Book 4A is available on AliExpress for just $188.80 without the CPU module for people who already own a Lichee LM4A system-on-module. You can buy a complete laptop with an 8GB/32GB variant at $298.40 and a 16GB/128GB variant at $348.80 on the same link. Shipping charges apply according to the delivery time of this product.
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