The MYC-C7Z015 CPU Module is an SOM (System on Module) board based on Xilinx XC7Z015 (Z-7015) All Programmable System-on-Chip (SoC) which is among the Xilinx Zynq-7000 family, featuring integrated dual-core ARM Cortex-A9 processor with Xilinx 7-series FPGA logic, four 6.25Gbps SerDes transceivers and one PCIe Gen2 x 4 integrated block. The MYC-C7Z015 module has 1GB DDR3 SDRAM, 4GB eMMC, 32MB quad SPI Flash, a Gigabit Ethernet PHY, a USB PHY and external watchdog on board. It provides a large number of I/O signals for ARM peripherals and FPGA I/Os through two 0.8mm pitch 140-pin board-to-board connectors, which is ideal for your next embedded design.
The MYC-C7Z015 CPU Module is compatible with MYIR’s MYC-C7Z010/20 CPU Modules and they can share the same base board which is designed by MYIR for evaluation or prototype purpose. The MYD-C7Z015 development board takes full features of the Zynq-7015 SoC. It has full features of the MYD-C7Z010/20 development board, additionally, it has one PCIe interface and one SFP transceiver module interface.
The MYC-C7Z015 CPU Module is ready to run Linux 3.15.0. It can be used in a variety of commercial, medical, automation, industrial, and military embedded applications.
Ls catalog thiet bi tu dong gm e_0908_dienhathe.vnDien Ha The
Khoa Học - Kỹ Thuật & Giải Trí: http://phongvan.org
Tài Liệu Khoa Học Kỹ Thuật: http://tailieukythuat.info
Thiết bị Điện Công Nghiệp - Điện Hạ Thế: http://dienhathe.org
The Rico Board is an excellent high-performance Single Board Computer using the newest TI’s AM437x Sitara ARM Cortex-A9 based solution. It has 512MB DDR3, 4GB eMMC Flash, 16MB QSPI Flash and 32KB EEPROM on board, featuring various peripherals like Debug Serial, USB, Gigabit Ethernet, Dual-Camera, TF, HDMI, LCD and etc. It is preloaded with Linux and supplied with optional 7-inch LCD Module including capacitive touch screen. More information can be found at MYIR's website: http://www.myirtech.com/list.asp?id=510
Ls catalog thiet bi tu dong gm e_0908_dienhathe.vnDien Ha The
Khoa Học - Kỹ Thuật & Giải Trí: http://phongvan.org
Tài Liệu Khoa Học Kỹ Thuật: http://tailieukythuat.info
Thiết bị Điện Công Nghiệp - Điện Hạ Thế: http://dienhathe.org
The Rico Board is an excellent high-performance Single Board Computer using the newest TI’s AM437x Sitara ARM Cortex-A9 based solution. It has 512MB DDR3, 4GB eMMC Flash, 16MB QSPI Flash and 32KB EEPROM on board, featuring various peripherals like Debug Serial, USB, Gigabit Ethernet, Dual-Camera, TF, HDMI, LCD and etc. It is preloaded with Linux and supplied with optional 7-inch LCD Module including capacitive touch screen. More information can be found at MYIR's website: http://www.myirtech.com/list.asp?id=510
Webinar: BlueNRG-LP - Bluetooth 5.2 de longo alcance para aplicações industriaisEmbarcados
O BlueNRG-LP é uma solução de SoC sem fio Bluetooth® Low Energy programável de ultrabaixa energia. Ele incorpora os IPs de rádio RF de 2,4 GHz de última geração da STMicroelectronics combinando desempenho incomparável com vida útil de bateria extremamente longa. É compatível com a especificação de núcleo Bluetooth® Low Energy SIG versão 5.2 endereçando conectividade ponto a ponto e rede Bluetooth Mesh e permite que redes de dispositivos em grande escala sejam estabelecidas de maneira confiável. O BlueNRG-LP também é adequado para comunicação sem fio de rádio proprietária de 2,4 GHz para lidar com aplicações de latência ultrabaixa.
Assista a gravação em: https://www.embarcados.com.br/webinars/webinar-bluenrg-lp-bluetooth-5-2-de-longo-alcance-para-aplicacoes-industriais/
I have collected all the necessary information about various hardware blocks of Nvidia Tegra K1 processor and put them together. It would be helpful for those who are/going to work on it by giving the details in a very concise fashion.
Webinar: BlueNRG-LP - Bluetooth 5.2 de longo alcance para aplicações industriaisEmbarcados
O BlueNRG-LP é uma solução de SoC sem fio Bluetooth® Low Energy programável de ultrabaixa energia. Ele incorpora os IPs de rádio RF de 2,4 GHz de última geração da STMicroelectronics combinando desempenho incomparável com vida útil de bateria extremamente longa. É compatível com a especificação de núcleo Bluetooth® Low Energy SIG versão 5.2 endereçando conectividade ponto a ponto e rede Bluetooth Mesh e permite que redes de dispositivos em grande escala sejam estabelecidas de maneira confiável. O BlueNRG-LP também é adequado para comunicação sem fio de rádio proprietária de 2,4 GHz para lidar com aplicações de latência ultrabaixa.
Assista a gravação em: https://www.embarcados.com.br/webinars/webinar-bluenrg-lp-bluetooth-5-2-de-longo-alcance-para-aplicacoes-industriais/
I have collected all the necessary information about various hardware blocks of Nvidia Tegra K1 processor and put them together. It would be helpful for those who are/going to work on it by giving the details in a very concise fashion.
MYC-Y6ULX CPU Module - NXP i.MX 6UL/6ULL System-on-ModuleLinda Zhang
This overview document gives a brief introduction of MYIR's MYC-Y6ULX CPU Module which is powered by NXP i.MX 6UltraLite / 6ULL processor based on the ARM Cortex-A7 architecture. It is ready to run Linux and delivers high performance with ultra-efficient power that targets Industry Control, Communications, HMI, Smart Healthcare and Internet of Things (IoT) applications. It carries out as many as peripheral signals and IOs through 1.0mm pitch 140-pin stamp hole expansion interface to allow customer’s extension for their next embedded design. The module can support industrial operating temperature range from -40 to +85 Celsius.
MYD-Y6ULX Development Board for i.MX 6UL/6ULL ARM Cortex-A7 ProcessorsLinda Zhang
The MYD-Y6ULX development board is a complete evaluation platform for NXP’s i.MX 6UltraLite / 6ULL processor family, which can operate at 528 MHz and features the most efficient ARM Cortex-A7 core, providing various memory interfaces and enhancing the flexibility and convenience of the board to connect peripheral devices. The board is ready to run Linux and supports industrial operating temperature range from -40 to +85 Celsius. employs the MYC-Y6ULX CPU Module as the controller board by populating the CPU Module on its base board through 1.0mm pitch 140-pin stamp hole interface. The MYC-Y6ULX CPU Module is mounted with a shield cover and integrated with core components including i.MX 6UltraLite / 6ULL processor, 256MB DDR3, 256MB Nand Flash or optional 4GB eMMC and Ethernet PHY. The base board has extended rich peripherals through connectors and headers like Serial ports, USB, Ethernet, CAN, Micro SD card, WiFi module, LCD/Touch screen, Camera, Audio as well as a Mini PCIe interface for optional USB based 4G LTE module. It is a versatile platform and solid reference design delivered with necessary cable accessories and detailed documentations ideal for prototype and evaluation based on i.MX 6UL/6ULL solutions.
MYS-6ULX Single Board Computer for Industry 4.0 and IoT ApplicationsLinda Zhang
The document introduced MYIR's i.MX 6UL / 6ULL based ARM Cortex-A7 Single Board Computer for Industry 4.0 and IoT applications which is ready to run Linux with high performance and ulta low cost.
MYC-YF13X CPU Module - STM32MP135 based SoMLinda Zhang
The MYC-YF13X CPU Module Overview gives introduction of the STM32MP135 processor based System-on-Module from MYIR, a Chinese company focused on providing SoM solutions for embedded appilcations. Measuring only 37mm by 39mm, the MYC-YF13X module has integrated the STM32MP135DAF7 processor, DDR3L, external memory and carried out a variety of peripheral and IO signals through the 1.0 mm pitch 148-pin Castellated-Hole expansion interface. It is capable of running Linux and provided with software resources including kernel and driver source code, together with detailed user manual and documentations to help customer start their development rapidly. It is particularly suitable for applications such as entry-level industrial human-machine interfaces (HMI) and embedded devices for energy and power management.
MYIR also provides the MYD-YF13X Development Board as a starter kit for evaluating the MYC-YF13X CPU Module. It has a versatile base board to facilitate the expansion from the MYC-YF13X through the 1.0 mm pitch 148-pin stamp-hole (Castellated-Hole) interface, a rich set of peripherals and interfaces have been brought out such as RS232, RS485, two USB 2.0 HOST and one USB 2.0 OTG, two Gigabit Ethernet, CAN, one Micro SD card slot, one USB based Mini-PCIe 4G Module interface with one SIM card holder, LCD interface, Camera interface, Audio input and output as well as two extension headers.
More information about the MYC-YF13X CPU Module can be found at:
https://www.myirtech.com/list.asp?id=726
The MYC-CZU3EG CPU Module is a powerful MPSoC System-on-Module (SoM) based on Xilinx Zynq UltraScale+ ZU3EG which features a 1.2 GHz quad-core ARM Cortex-A53 64-bit application processor
The MYD-YA15XC-T development board is using the MYC-YA15XC-T CPU Module as core controller board which is populated on a specially designed base board through 1.0 mm pitch 148-pin stamp-hole (Castellated-Hole) expansion interface. The MYD-YA15XC-T is a good reference design for using ST STM32MP1 Processors which features 650MHz Single or Dual Arm Cortex-A7 and 209MHz Cortex-M4 Cores. Typical applications are industrial control, consumer electronics, smart home, medical and more other energy-efficient applications which require rich performance and low power. More information can be found at:
http://www.myirtech.com/list.asp?id=659
The MYD-J1028X development board consists ofthe high-performance MYC-J1028X CPU Module and a base board to provide a complete evaluation platform for NXP LS1028A Processor which features dual Arm Cortex-A72 cores,with integrated 3D GPU for HMI, and a time-sensitive networking (TSN) -enabled Ethernet switch and Ethernet controllers to support converged IT and OT networks. Typical applications are industrial router, industrial control, edge computing, automotive electronics, industrial IoT and other scenes requiring high reliability, powerful communication and display capabilities.
The MYC-J1028X CPU Module is an ARM SoM with Layerscape LS1028A SoC, 2G DDR4, 8GB eMMC, 32Kbit EEPROM and a temperature sensor. It is connected to the base board of MYD-J1028X through one 0.5mm pitch 314-pin MXM 3.0 gold-finger-edge-card connector. The base board has brought out rich peripherals through connectors and headers such as 5G Module interface, one M.2 Key B based SSD Module interface,one DP display port, one Audio output port, one Micro SD card slot as well as two SIM card slots and more others.
he MYD-J1028X development board is delivered with one Quick Start Guide, one Type-C cable, one 12V/2A power adapter and one DC power jack adapter to provide user a complete platform for evaluating and prototyping based on LS1028A processor. MYIR also offers MY-CAM002U USB Camera Module and MY-WIREDCOM RPI Module (RS232/RS485/CAN) as options for the board.
The MYD-J1028X is capable of supporting Ubuntu and Real-time Edge images based on Linux kernel. Driver source code and compilation tools are provided to enable users to start their development rapidly and easily.
Measuring 45mm by 82mm, the MYC-J1028X CPU Module is a high-performance embedded ARM SoM for industrial and automotive applications. It is based on NXP LS1028A SoC of the Layerscape family and features 1.5 GHz dual Arm Cortex-A72 cores, with integrated 3D GPU for HMI, and a time-sensitive networking (TSN) -enabled Ethernet switch and Ethernet controllers to support converged IT and OT networks. The MYC-J1028X has 2GB DDR4 and supports multiple external memory options including 8GB eMMC (default), QSPI NAND Flash (DNP) and XSPI NOR Flash (DNP). It has 32Kbit EEPROM and one temperature sensor on the rear of the board. A number of peripheral and IO signals are access through one 0.5mm pitch 314-pin MXM 3.0 gold-finger-edge-card connector. It is capable of supporting Ubuntu and Real-time Edge images based on Linux kernel.
The MYD-J1028X Development Board is using the MYC-J1028X as core controller board and has explored the features of the LS1028A processor to serve as an solid reference design for customer’s development. The base board has brought out rich peripherals through connectors and headers such as one USB3.0 Host, five Gigabit TSN Ethernet, one M.2 Key E based WiFi module interface, one USB 3.0 M.2 Key B based 5G Module interface, one M.2 Key B based SSD Module interface, one DP display port, one Audio output port, one Micro SD card slot as well as two SIM card slots and more others.
Measuring only 39mm by 37mm, the MYC-YA15XC-T CPU Module is MYIR’s another System-on Module (SoM) based on ST STM32MP1 series processors after the first release of the MYC-YA157C CPU Module, The new MYC-Y157XC-T module has integrated the STM32MP151AAC3T processor by default and a dedicated Power Management IC STPMIC1 also from STMicroelectronics. It has onboard DDR3L, Nand Flash or eMMC and 32KB EEPROM. A number of peripherals and IO signals are brought out through 1.0 mm pitch 148-pin stamp-hole (Castellated-Hole) expansion interface to make the module an excellent embedded controller for applications like industrial control, consumer electronics, smart home, medical and etc. The MYC-YA15XC-T is running Linux with provided 5.4.31 kernel and many drivers in source code.
Powerful SoM based on i.MX 8M Mini processor for various embedded applicationsnie, jack
Measuring 60mm by 49mm, the MYC-C8MMX CPU Module is a low-cost embedded ARM SoM based on NXP’s first embedded multicore applications processor i.MX 8M Mini which features up to 1.8GHz quad-core ARM Cortex-A53 plus 400MHz Cortex-M4 processor,
The MYS-8MMX Single Board Computer has a compact design with only 95mm by 65mm form factor. It is powered by NXP’s first embedded multicore applications processor i.MX 8M Mini which features up to 1.8GHz quad-core ARM Cortex-A53 plus 400MHz Cortex-M4 processor. The tiny board takes full features of the processor and is equipped with 2GB DDR4, 8GB eMMC and 32MB QSPI Flash. It has explored rich peripheral interfaces through headers and connectors including two USB 2.0 Host, one USB OTG, one Gigabit Ethernet, TF card, M.2 interface, LVDS LCD interface, MIPI CSI interface, HDMI output, IO expansion interface and more others. The AP6256 WiFi/BT module on the board also allows wireless communications with other devices. It is capable of running Linux operating system based on the Yocto 3.0 or Ubuntu 18.04 .
The MYD-YT507H Development Board consists of a compact CPU Module MYC-YT507H and a base board to provide a complete evaluation platform for ALLWINNER T507-H Processor which among Allwinner T5 series with a 1.5GHz quad-core Cortex-A53 CPU and a Mali-G31 MP2 GPU. The processor is AEC-Q100 certified and targets the new generation of automotive markets. Typical applications are power IoT, automotive electronics, commercial display, industrial control, medical devices, intelligent terminals and more others.
The MYD-YT507H has a base board which installed MYC-YT507H CPU Module through 1.0mm pitch 222-pin stamp-hole (Castellated-Hole) interface. The MYC-YT507H CPU Module is a highly-integrated SoM which combines the ALLWINNER T507-H processor, 1GB/2GB DDR4, 8GB eMMC, 32Kbit EEPROM and PMIC. The base board is explored with Serial ports, one Gigabit Ethernet and one 10/100M bps Ethernet, two USB 2.0 HOST and one USB 2.0 OTG, one TF card slot as well as a USB based 4G Mini PCIE interface. It has a DVP camera interface and a MIPI-CSI interface to allow connecting with camera modules. It also supports multi video output interfaces such as dual LVDS, HDMI and CVBS OUT, to achieve different display in dual screens.
The MYD-YT507H Development Board is delivered with one Quick Start Guide, one USB cable, one 12V/2A power adapter and one DC power jack adapter to provide user a complete platform for evaluating and prototyping based on T507 processor. MYIR also offers MY-CAM002U USB Camera Module, MY-CAM011B DVP Camera Module, MY-CAM003M MIPI Camera Module, MY-WIREDCOM RPI Module (RS232/RS485), MY-WF005S WiFi/BT Module and MY-LVDS070C LCD Module as options for the board which have greatly enhanced the functionality of the board.
The MYD-YT507H is running Linux OS. MYIR provides abundant software resources for Linux 4.9 based MYIR MEasy HMI V2.0 system with QT5.12.5, Ubuntu 18.04.5 system, including kernel, driver source codes and compilation tools to enable users to start their development rapidly and easily.
Measuring only 43mm by 45mm, the MYC-YT507H CPU Module is a compact System-on Module (SoM) based on Allwinner T507-H industrial processor which among Allwinner T5 series with a 1.5GHz quad-core Cortex-A53 CPU and a Mali-G31 MP2 GPU. The processor is AEC-Q100 certified and targets the new generation of automotive markets. Additionally, it has onboard 1GB/2GB LPDDR4, 8GB eMMC, 32Kbit EEPROM and Power management IC (PMIC). SMD packaging is adopted to save connector cost. A variety of peripheral and IO signals are accessible via the 1.0 mm pitch 222-pin stamp-hole (Castellated-Hole) expansion interface. With strong performance, extensive peripheral resources and low cost, the MYC-YT507H can be used in a wide range of applications such as power IOT, automotive electronics, commercial display, industrial control, medical devices, intelligent terminals, and more others.
The MYC-YT507H is running Linux 4.9 with ported Ubuntu 18.04.5 and MYIR MEasy HMI V2.0 system with QT5.12.5, supporting systems with XFCE graphics function. MYIR has provided the software development resources with kernel and drivers all in source code.
MYIR provides MYD-YT507H development board for evaluating the MYC-YT507H CPU Module. It takes full advantages of the Allwinner T5 MPU to explore a rich set of peripherals and interfaces to the base board including Serial ports, one Gigabit Ethernet and one 10/100M bps Ethernet, two USB 2.0 HOST and one USB 2.0 OTG, one TF card slot as well as a USB based 4G Mini PCIE interface. It has a DVP camera interface and a MIPI-CSI interface to allow connecting with camera modules. It also supports multi video output interfaces such as dual LVDS, HDMI and CVBS OUT, to achieve different display in dual screens.
FZ3 Card - Deep Learning Accelerator CardLinda Zhang
The FZ3 Card is a powerful deep learning accelerator card based on Xilinx Zynq UltraScale+ ZU3EG MPSoC which features a 1.2 GHz quad-core ARM Cortex-A53 64-bit application processor, a 600MHz dual-core real-time ARM Cortex-R5 processor, a Mali400 embedded GPU and rich FPGA fabric. Besides, it integrates 4GB DDR4, 8GB eMMC, 32MB QSPI Flash and 32KB EEPROM as well as many peripherals including USB 2.0, USB 3.0, Gigabit Ethernet, TF, DisplayPort (DP), PCIe interface, MIPI-CSI, BT1120 camera, USB-UART, JTAG, IO expansion interfaces, etc. The rich resources enable users to integrate intelligent hardware easily.
The FZ3 Card is able to run PetaLinux 2019.1 and supports PaddlePaddle deep learning AI framework which is fully compatible to use Baidu Brain’s AI development tools like EasyDL, AI Studio and EasyEdge to enable developers and engineers to quickly leverage Baidu-proven technology or deploy self-defined models, enabling faster deployment. Typical applications are AI camera, AI computing device, robotics, intelligent car, intelligent electronic scale, patrol UAV and other embedded intelligent applications.
This book is written by Mr.Joseph Attard, a Senior lecturer II working at Malta College for Arts Science and Technology on the island of Malta. In this book, Joseph shared a lot of content on how to work with MYIR's Z-turn board, starting from simply creating a project in Vivado to flash an LED, continuing to Detecting Switch inputs, all the way to interfacing the Xilinx Zynq 7 System on Chip to multiple analogue sensors through multiple XADC channels. All the above-mentioned interfacing is done from both the ARM Cortex A9, commonly known as the Processing System and the Artix 7 FPGA, commonly known as Programmable Logic, both residing within the Zynq 7000 SoC.
Verification of EMC Compliance for MYC-Y6ULX CPU ModuleLinda Zhang
The file has presented the verification of EMC compliance for MYIR's MYC-Y6ULX CPU Module which is an system-on-module (SoM) powered by NXP i.MX 6UltraLite / 6ULL processor based on the ARM Cortex-A7 architecture. The module is ready to run Linux and can support industrial operating temperature range from -40 to +85 Celsius.
Development Board for NXP i.MX 8M Quad Application ProcessorsLinda Zhang
The overview file introduces a versatile platform MYD-JX8MX development board for evaluating the MYC-JX8MX CPU Module. It takes full features of the i.MX 8M processor and has brought out rich peripherals through connectors and headers such as 4 x USB 3.0 Host ports and 1 x USB 3.0 Host/Device port, Gigabit Ethernet, TF card slot, USB based Mini PCIe interface for 4G LTE Module, WiFi/BT, Audio In/Out, HDMI, 2 x MIPI-CSI, MIPI-DSI, 2 x LVDS display interfaces, PCIe 3.0 (x4) NVMe SSD Interface, etc. The board is ready to run Linux and can work in extended temperature ranging from -30°C to 80°C. It is delivered with necessary cable accessories for customers to easily start development as soon as getting it out-of-box. A MIPI Camera Module MY-CAM003 is provided as an option for the board.
High-performance ARM SoM Powered by NXP i.MX 8MLinda Zhang
The document file has introduced MYIR's high-performance ARM SoM MYC-JX8MX CPU Module, which is built around the NXP i.MX 8M Quad processor featuring 1.3GHz quad ARM Cortex-A53 cores and a real-time ARM Cortex-M4 co-processor. The module runs Linux and is capable of working in extended temperature ranging from -30°C to 80°C.
This technical paper has collected and summarized some frequently asked questions (FAQs) by MYIR's engineers on development based on NXP's i.MX 6UL/6ULL ARM Cortex-A7 processors. Hope it can help developers during their work.
The catalogue includes helpful information on different ARM based products available from MYIR Tech Limited such as development boards, single board computers, CPU modules and so on.
Atmel SAMA5D4 Development Board and CPU ModuleLinda Zhang
This document introduces MYIR's MYD-JA5D4X development board and MYC-JA5D4X CPU Module which are based on Atmel’s ARM Cortex-A5 based SAMA5D42 orSAMA5D44 ARM Cortex-A5 processor, capable of running Linux and support extended operation temperature.
Atmel SAMA5D3 Development Boards and CPU ModulesLinda Zhang
This documentation introduces MYIR's development boards and CPU Modules based on Atmel's SAMA5D3 ARM Cortex-A5 processors, capable of running Linux and Android and can work in harsh environment supporting -40 to +85 Celsius extended temperature operation for industrial embedded applications.
The MYD-C7Z010/20 development board is built around the MYC-C7Z010/20 CPU Module which is a compact Linux-ready ZYNQ-based SOM (System on Module). The MYC-C7Z010/20 combines the Xilinx XC7Z010 (ZYNQ-7010) or XC7Z020 (ZYNQ-7020) SoC device, 1GB DDR3 SDRAM, 4GB eMMC, 32MB quad SPI Flash, a Gigabit Ethernet PHY, a USB PHY and external watchdog. It is connected to the MYD-C7Z010/20 base board through two 0.8mm pitch 140-pin board-to-board connectors. The MYD-C7Z010/20 development board is delivered with necessary cable accessories and MYIR offers optional 4.3-inch and 7-inch LCD Module. The board is preloaded with Linux. It is a high-performance and low-cost development platform for evaluation and prototype based on Xilinx Zynq-7000 All Programmable SoC family.
Transforming Brand Perception and Boosting Profitabilityaaryangarg12
In today's digital era, the dynamics of brand perception, consumer behavior, and profitability have been profoundly reshaped by the synergy of branding, social media, and website design. This research paper investigates the transformative power of these elements in influencing how individuals perceive brands and products and how this transformation can be harnessed to drive sales and profitability for businesses.
Through an exploration of brand psychology and consumer behavior, this study sheds light on the intricate ways in which effective branding strategies, strategic social media engagement, and user-centric website design contribute to altering consumers' perceptions. We delve into the principles that underlie successful brand transformations, examining how visual identity, messaging, and storytelling can captivate and resonate with target audiences.
Methodologically, this research employs a comprehensive approach, combining qualitative and quantitative analyses. Real-world case studies illustrate the impact of branding, social media campaigns, and website redesigns on consumer perception, sales figures, and profitability. We assess the various metrics, including brand awareness, customer engagement, conversion rates, and revenue growth, to measure the effectiveness of these strategies.
The results underscore the pivotal role of cohesive branding, social media influence, and website usability in shaping positive brand perceptions, influencing consumer decisions, and ultimately bolstering sales and profitability. This paper provides actionable insights and strategic recommendations for businesses seeking to leverage branding, social media, and website design as potent tools to enhance their market position and financial success.
You could be a professional graphic designer and still make mistakes. There is always the possibility of human error. On the other hand if you’re not a designer, the chances of making some common graphic design mistakes are even higher. Because you don’t know what you don’t know. That’s where this blog comes in. To make your job easier and help you create better designs, we have put together a list of common graphic design mistakes that you need to avoid.
Dive into the innovative world of smart garages with our insightful presentation, "Exploring the Future of Smart Garages." This comprehensive guide covers the latest advancements in garage technology, including automated systems, smart security features, energy efficiency solutions, and seamless integration with smart home ecosystems. Learn how these technologies are transforming traditional garages into high-tech, efficient spaces that enhance convenience, safety, and sustainability.
Ideal for homeowners, tech enthusiasts, and industry professionals, this presentation provides valuable insights into the trends, benefits, and future developments in smart garage technology. Stay ahead of the curve with our expert analysis and practical tips on implementing smart garage solutions.
Hello everyone! I am thrilled to present my latest portfolio on LinkedIn, marking the culmination of my architectural journey thus far. Over the span of five years, I've been fortunate to acquire a wealth of knowledge under the guidance of esteemed professors and industry mentors. From rigorous academic pursuits to practical engagements, each experience has contributed to my growth and refinement as an architecture student. This portfolio not only showcases my projects but also underscores my attention to detail and to innovative architecture as a profession.
7 Alternatives to Bullet Points in PowerPointAlvis Oh
So you tried all the ways to beautify your bullet points on your pitch deck but it just got way uglier. These points are supposed to be memorable and leave a lasting impression on your audience. With these tips, you'll no longer have to spend so much time thinking how you should present your pointers.
Between Filth and Fortune- Urban Cattle Foraging Realities by Devi S Nair, An...Mansi Shah
This study examines cattle rearing in urban and rural settings, focusing on milk production and consumption. By exploring a case in Ahmedabad, it highlights the challenges and processes in dairy farming across different environments, emphasising the need for sustainable practices and the essential role of milk in daily consumption.
1. MYC-C7Z015 CPU Module
- 667MHz Xilinx XC7Z015 Dual-core ARM Cortex-A9 Processor with Xilinx 7-series FPGA logic
- 1GB DDR3 SDRAM (2 x 512MB, 32-bit), 4GB eMMC, 32MB QSPI Flash
- On-board Gigabit Ethernet PHY
- Two 0.8mm pitch 140-pin Board-to-Board Expansion Connectors
- Ready-to-Run Linux 3.15.0
Figure 1-1 MYC-C7Z015 CPU Module
The MYC-C7Z015 CPU Module is an SOM (System on Module) board based on Xilinx XC7Z015 (Z-7015) All
Programmable System-on-Chip (SoC) which is among the Xilinx Zynq-7000 family, featuring integrated
dual-core ARM Cortex-A9 processor with Xilinx 7-series FPGA logic, four 6.25Gbps SerDes transceivers and
one PCIe Gen2 x 4 integrated block. The MYC-C7Z015 module has 1GB DDR3 SDRAM, 4GB eMMC, 32MB
quad SPI Flash, a Gigabit Ethernet PHY, a USB PHY and external watchdog on board. It provides a large
number of I/O signals for ARM peripherals and FPGA I/Os through two 0.8mm pitch 140-pin
board-to-board connectors, which is ideal for your next embedded design.
Figure 1-2 MYC-C7Z015 CPU Module
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2. The MYC-C7Z015 CPU Module is compatible with MYIR’s MYC-C7Z010/20 CPU Modules and they can share
the same base board which is designed by MYIR for evaluation or prototype purpose. The MYD-C7Z015
development board takes full features of the Zynq-7015 SoC. It has full features of the MYD-C7Z010/20
development board, additionally, it has one PCIe interface with two lanes and one SFP transceiver module
interface.
The MYC-C7Z015 CPU Module is ready to run Linux 3.15.0. It can be used in a variety of commercial,
medical, automation, industrial, and military embedded applications.
Figure 1-3 MYD-C7Z015 Development Board
Hardware Specification
The Zynq™-7000 family of devices combines the software programmability of a Processor with the
hardware programmability of an FPGA, resulting in unrivaled levels of system performance, flexibility,
scalability while providing system benefits in terms of power reduction, lower cost with fast time to market.
Unlike traditional SoC processing solutions, the flexible programmable logic of the Zynq-7000 devices
enables optimization and differentiation, allowing designers to add peripherals and accelerators to adapt to
a broad base of applications.
The Zynq-7000 AP SoC leverages the 28nm scalable optimized programmable logic used in Xilinx’s 7 series
FPGAs. Each device is designed to meet unique requirements across many use cases and applications. The
Z-7010, Z-7015, and Z-7020 leverage the Artix®-7 FPGA programmable logic and offer lower power and
lower cost for high-volume applications. The Z-7030, Z-7035, Z-7045, and Z-7100 are based on
the Kintex®-7 FPGA programmable logic for higher-end applications that require higher performance and
high I/O throughput.
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3. Z-7010 Z-7015 Z-7020 Z-7030 Z-7035 Z-7045 Z-7100
Processor Core Dual ARM® Cortex™-A9 MPCore™ with CoreSight™
Processor
Extensions
NEON™ & Single / Double Precision Floating Point for each processor
L1 Cache 32 KB Instruction, 32 KB Data per processor
L2 Cache 512 KB
On-Chip Memory 256 KB
Memory
Interfaces
DDR3, DDR3L, DDR2, LPDDR2, 2x Quad-SPI, NAND, NOR
Peripherals 2x USB 2.0 (OTG), 2x Tri-mode Gigabit Ethernet, 2x SD/SDIO
Logic Cells
28K Logic
Cells
74K Logic
Cells
85K Logic
Cells
125K Logic
Cells
275K Logic
Cells
350K Logic
Cells
444K Logic Cells
BlockRAM (Mb) 240 KB 380 KB 560 KB 1,060 KB 2,000 KB 2,180 KB 3,020 KB
DSP Slices 80 160 220 400 900 900 2,020
Transceiver
Count
4 (6.25
Gb/s)
up to 4 (12.5
Gb/s)
up to 16 (12.5
Gb/s)
up to 16 (12.5
Gb/s)
up to 16 (10.3125
Gb/s)
Table 1-1 ZYNQ-7000 Devices
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4. Figure 1-4 Zynq-7000 Devices
Mechanical Parameters
Dimensions: 75mm x 55mm (12-layer PCB design)
Power supply: 5V/0.5A
Working temp.: 0~70 Celsius (commercial grade)
SoC
Xilinx XC7Z015-1CLG485C (Zynq-7015)
- 667MHz ARM® dual-core Cortex™-A9 MPCore processor (up to 866MHz)
- Integrated Artix-7 class FPGA subsystem with 74K logic cells, 46,200 LUTs, 160 DSP slices
- NEON™ & Single / Double Precision Floating Point for each processor
- Supports a Variety of Static and Dynamic Memory Interfaces
- Four high-speed SerDes transceivers up to 6.25Gbps
- Four PCIe Gen2 hardened, integrated IP blocks
Memory
1GB DDR3 SDRAM (512MB*2)
4GB eMMC
32MB QSPI Flash (16MB is optional)
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5. Peripherals and Signals Routed to Pins
One 10/100/1000M Ethernet PHY with SGMII
One USB 2.0 ULPI PHY
External watchdog
Three LEDs
- One blue LED for power indicator
- One red LED for FPGA program done indicator
- One green user LED
Two 0.8mm pitch 140-pin board-to-board expansion connectors bring out below signals:
- One Gigabit Ethernet (PS Ethernet 0)
- One USB OTG 2.0 (PS USB 0)
- Up to two Serial ports (reused from PS_MIO, can also be implemented through PL pins)
- Up to two I2C (reused from PS_MIO, can also be implemented through PL pins)
- Up to two CAN BUS (reused from PS_MIO, can also be implemented through PL pins)
- One SPI (reused from PS_MIO, can also be implemented through PL pins)
- ADC (one independent differential ADC, 16-channel ADC brought out through PL pins)
- One SDIO (PS SDIO 0)
- Bank 13 (PL I/O configurable as up to 18 LVDS pairs and 1 single-ended I/O or 37 single-ended I/O)
- Bank 34 (PL I/O configurable as up to 24 LVDS pairs and 2 single-ended I/O or 50 single-ended I/O)
- Bank 35 (PL I/O configurable as up to 24 LVDS pairs and 2 single-ended I/O or 50 single-ended I/O)
- Bank 112 (4 GTP serial transceivers, 2 reference clock input)
Function Block Diagram
Figure 1-5 MYC-C7Z015 Function Block Diagram
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6. Dimension Chart
Figure 1-6 Dimensions of MYC-C7Z015
Expansion Connectors
The MYC-C7Z015 CPU Module is using two 0.8mm pitch 140-pin board-to-board female connectors for
extension. Please refer to the file “MYC-C7Z015 Pin description Table” to know the signals routed to the
connectors. You can download the file from MYIR’s website: www.myirtech.com.
Figure 1-7 Expansion Connectors of MYC-C7Z015
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7. Software Features
The MYC-C7Z015 CPU Module is capable of running Linux 3.15.0. MYIR provides software package in
product disk along with the goods delivery. The software package features as below:
Item Features Description Remark
Cross
compiler
gcc 4.6.1
gcc version 4.6.1
(Sourcery CodeBench Lite 2011.09-50)
Boot
program
BOOT.BIN First boot program including FSBL, bitstream Source code provided
u-boot Secondary boot program Source code provided
Linux Kernel Linux 3.15.0 Customized kernel for MYD-C7Z010/20 Source code provided
Drivers
USB Host USB Host driver Source code provided
PCI-E PCIE driver Source code provided
SFP SFP transceiver driver Source code provided
Ethernet Gigabit Ethernet driver Source code provided
MMC/SD/TF MMC/SD/TF card driver Source code provided
CAN CAN driver Source code provided
LCD Controller XYLON LCD driver Source code provided
HDMI HDMI (SII902X chip) driver Source code provided
Button Button driver Source code provided
UART Serial port driver Source code provided
LED LED driver Source code provided
GPIO GPIO driver Source code provided
QSPI QSPI Flash S25FL256S driver Source code provided
RTC DS3231 RTC driver Source code provided
Resistive Touch TSC2007 resistive touch screen driver Source code provided
Capacitive Touch FT5X0X capacitive touch screen driver Source code provided
ADC ADC driver Source code provided
File System
Ramdisk Ramdisk system image
Rootfs.tar Tar file
Table 1-2 Linux Software Package Features
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8. Order Information
Item Part No. Packing List
MYC-C7Z010
CPU Module
MYC-C7Z015-4E1D-667-C
One MYC-C7Z015 CPU Module (for Zynq-7015)
One Product DVD
MYD-C7Z015
Development Board
MYC-C7Z015-4E1D-667-C
One MYD-C7Z015 board
One 1.5m cross Ethernet cable
One DB9 UART cable
One HDMI cable
One 12V/1.25A Power adapter
One product disk
(including user manual, base board schematic in
PDF format, datasheets and software package)
MYIR Tech Limited
Room 1306, Wensheng Center, Wenjin Plaza, North Wenjin Road, Luohu District,
Shenzhen, China 518020
E-mail: sales@myirtech.com
Phone: +86-755-22984836
Fax: +86-755-25532724
Website: http://www.myirtech.com
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