Tag: arduino (page 1 of 4)

7″ Portable Raspberry Pi Multi-Touch Tablet



In this project, we’ll show you how to build a portable Raspberry Pi 2, using a 7″ touchscreen display, an Adafruit PowerBoost 1000c and a 2500mAh battery. Our 3D printed enclosure fits all of the components making an all-in-one, compact Raspberry Pi tablet.

Full Tutorial:
https://learn.adafruit.com/7-portable-raspberry-pi-multitouch-tablet/overview

Download STLs:
http://www.thingiverse.com/thing:1082431

Previous Project:

3D Printed Cosplay – Avengers Wasp

3D Printing Projects Playlist:

3D Hangout Show Playlist:

Layer by Layer CAD Tutorials Playlist:

Connect with Noe and Pedro on Social Media:

Noe’s Twitter / Instagram: @ecken
Pedro’s Twitter / Instagram: @videopixil

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Subscribe to Adafruit on YouTube: http://adafru.it/subscribe

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Watch our latest project videos: http://adafru.it/latest

New tutorials on the Adafruit Learning System: http://learn.adafruit.com/

Music by Noe Ruiz: http://soundcloud.com/ecken
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source

Relevant Stories

The Raspberry Pi Zero W Offers Wi-Fi and Bluetooth to the Zero, Costs $10
http://lifehacker.com/the-raspberry-pi-zero-wireless-adds-wi-fi-and-bluetooth-1792789503

Hands-On: A case for the Raspberry Pi Zero with camera
http://www.zdnet.com/article/hands-on-a-case-for-the-raspberry-pi-zero-with-camera/

Pack a Raspberry Zero and Screen Into an Altoids Container for a Lightweight Tiny Computer
http://lifehacker.com/cram-a-raspberry-zero-and-screen-into-an-altoids-tin-fo-1792394348

Best Five Raspberry Pi Zero Electronics Projects Which Make The Most Of Its Tiny Measurement

The Raspberry Pi is definitely the hobbyist option for Build-it-yourself electronic projects. The Raspberry Pi Zero, that’s around the measurements of a stick of chewing gum, is comparatively low priced and has it’s own special use examples though. There are ten of our most liked projects which make the most of its measurement.

1. Cram a Raspberry Pi Zero Into an Old-fashioned Game Controller

It is well known the Raspberry Pi makes an nice DIY computer game console. The setup process merely demands a matter of minutes, and the Raspberry Pi Zero is utterly efficient at coping with older computer games from the SNES age and perhaps earlier. The complete project is far better when the whole system is inside a controller.

Working example (ahem), this project utilizes a SNES controller, this one tackles the NES controller, and this one uses that good old original Xbox controller. However you intend to practice it, you will have a really slick little DIY classic video game console you can easily carry around wherever.

2. Build a Tiny Dongle Computer

While the Pi Zero makes a nice little computer as it is, it makes an even better dongle computer. By doing so, you can attach it to some other computer you have, then it will tether itself directly so you won’t need to include a USB or any networking.

The most wonderful thing of this project is the point you no longer need yet another PC mouse, display screen, or keyboard hanging out around. Simply just jam in into your standard desktop PC and you are fine.

3. Build the Planet’s Minutest (Potentially) MAME Cabinet

MAME cabinets are brilliant, but they are tremendous. For the complete opposite approach, you can make use of a Raspberry Pi Zero to make one that is almost as tiny as the Pi itself.

You may need a few items to build this sucker work, for example a 3D printed case, but in the end cabinet is extremely functional, which means you’ll have the best desk add-on in the office.

4. Make a Motion Sensing Digicam


source: http://instructables.com/id/Raspberry-Pi-Motion-Sensing-Camera/

The Raspberry Pi has been a top quality motion sensing camera, but the low profile of the Pi Zero makes it even better.

Employing the Raspberry Pi Zero, your motion sensing camera has a smaller foot print, indicating it can go in even tighter rooms. To illustrate, this one mounts to your window with a pair of suction cups, which is nearly as lightweight as it can get.

5. Play Any Simpsons Episode (or perhaps Any Television Program) At Random

If you have ditched cable and gone full streaming with your media, you might still miss the days of catching a random episode of your most enjoyable show on TV. The Raspberry Pi Zero can bring that back.

In this project, they use episodes of The Simpsons stored on an Sdcard. With a custom script, you possibly can press a button and it plays an episode arbitrarily. You may increase any media you’d like here, including several shows if you wanted, however, The Simpsons are a wonderful option.

Weekly Roundup #15 – New Maker Products



This week’s Weekly Roundup we’re seeing noise makers, more LEDs, no robots, the fastest RISC based Arduino compatible board and a new SBC that’ll raise the bar even further.

See below for links and also on my website.

More Info:

Weekly Roundup #15 – New Maker Products

Support Me:
Patreon: https://www.patreon.com/MickMake

Feedback Me:
Email: feedback@mickmake.com

Follow Me:
YouTube: https://www.youtube.com/c/MickMakes
Facebook: https://www.facebook.com/MickMakes/
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Github: https://github.com/MickMakes

# Kickstarter
Caddy Board

1Bitsy & Black Magic Probe
https://www.kickstarter.com/projects/esden/1bitsy-and-black-magic-probe-demystifying-arm-prog
Firefly RK3399
https://www.kickstarter.com/projects/1771382379/firefly-rk3399-six-core-64-bit-high-performance-pl
The Yowler
https://www.kickstarter.com/projects/218568730/the-yowler-a-community-built-diy-noise-synth

# IndieGoGo
NaviPack
https://www.indiegogo.com/projects/navipack-lidar-navigation-module-reinvented#/
OverLord Plus
https://www.indiegogo.com/projects/overlord-plus-the-most-reliable-delta-3d-printer–2#/
The Tiny-TS
https://www.indiegogo.com/projects/the-tiny-ts-an-open-sourced-diy-touch-synthesizer#/

# CrowdSupply
AAduino
https://www.crowdsupply.com/johan-kanflo/aaduino
BES-AFE-1
https://www.crowdsupply.com/signal-lattice/bes-afe-1
Open-V
https://www.crowdsupply.com/onchip/open-v
HiFive1
https://www.crowdsupply.com/sifive/hifive1

# Others
AWS Greengrass
https://aws.amazon.com/greengrass/

# Tindie
868Mhz 915Mhz SX1276 Lora Module with ATmega328P
https://www.tindie.com/products/Armtronix/868mhz-915mhz-sx1276-lora-module-with-atmega328p/
Zero Long
https://www.tindie.com/products/microwavemont/zero-long-a-wider-oled-samd21g18a-boardw-microsd/
Flexible LED Array 32×32
https://www.tindie.com/products/robogeek78/flexible-led-array-32×32-ws2812-ws2813-/
WiThumb
https://www.tindie.com/products/HackARobot/withumb-arduino-compatible-wifi-usb-thumb–imu/
E2450
https://www.tindie.com/products/LOCUS_ENG_INC/e2450-lost-rc-aircraft-beacon/
OpenHome Security Gateway
https://www.tindie.com/products/vysocan/openhome-security-gateway-17-/

# AdaFruit, Seeed, SparkFun, DFRobot, DigiKey
RF Explorer 3G+
https://www.seeedstudio.com/RF-Explorer-3G%2B-IoT-for-Raspberry-Pi-p-2770.html
VL6180X Breakout
https://www.adafruit.com/products/3316
Pi Powered Times Square Traveler Pack
https://www.adafruit.com/products/3273
MAX30105 Breakout
https://www.sparkfun.com/products/14045
Flexible LED Array 16×16
https://www.dfrobot.com/index.php?route=product/product&path=48&product_id=1556&sort=p.date_added&order=DESC
Flexible LED Array 8×8
https://www.dfrobot.com/index.php?route=product/product&path=48&product_id=1557&sort=p.date_added&order=DESC

# The Cheap Side
Maple Leaf clone
http://www.banggood.com/STM32-ARM-Cortex-M3-Leaflabs-Leaf-Maple-Mini-Module-For-Arduino-p-1110609.html
RTL8710 WiFi Module
http://www.banggood.com/RTL-01-RTL8710-WIFI-Module-3V-3_6V-80MA-Far-Distance-Wireless-Transceiver-Module-p-1110579.html
Wemos D1 clone
http://www.banggood.com/Wemos-D1-Mini-Kit-Mini-NodeMcu-4M-Bytes-Lua-WIFI-Internet-of-Things-Development-Board-Based-ESP8266-p-1110584.html
ADS1015 12 bit ADC
http://www.banggood.com/ADS1015-12-Bit-Precision-Analog-To-Digital-Converter-ADC-Module-Development-Board-p-1110605.html
DIY Smoke Detector
http://www.banggood.com/DIY-Photoelectric-Smoke-Detector-Sensor-Alarm-Kit-Electronic-Training-Teaching-p-1110265.html
AD8232 ECG
http://www.banggood.com/AD8232-ECG-Pulse-Monitoring-Measurement-Sensor-Module-Kit-For-Arduino-p-1109781.html
1.44″ TFT
http://www.banggood.com/1_44-TFT-Full-Color-SPI-Serial-Port-Screen-Display-With-PCB-Backplate-p-1109762.html
2.2″ 320×240 TFT
http://www.banggood.com/2_2-320×240-TFT-Screen-LCD-Display-HAT-With-Buttons-IR-Sensor-For-Raspberry-Pi-3B-2B-B-p-1109780.html
1.3″ 128×64 OLED

1.30inch 128×64 SPI Interface OLED White,Blue


ESP32
http://www.banggood.com/ESP32-Development-Board-WiFiBluetooth-Ultra-Low-Power-Consumption-Dual-Cores-ESP-32-ESP-32S-Board-p-1109512.html
NodeMCU-32S
http://www.shenzhen2u.com/NodeMCU-32S
BME280 Atmospheric Sensor
http://www.elecrow.com/crowtail-bme280-atmospheric-sensor-2331.html
AK09911C Hall Sensor
http://www.icstation.com/cjmcu-9911-ak09911c-geomagnetism-hall-sensor-module-arduino-stm32-p-10573.html
4-Port USB hub
http://www.icstation.com/cjmcu-port-controller-module-electronic-components-p-10571.html

Source

IoT PCB considerations for Startups

Since IoT products are so cutting edge, you would think that getting an IoT printed circuit board (PCB) project off the ground starts by reinventing the wheel and dealing with a number of technical complications. This is incorrect.
But it doesn’t indicate IoT startups have a obvious route to fame. Facing them is numerous design and manufacturing factors to consider that are unique to these small products. These things to consider are required to be looked at for the fresh IoT product to gain success.

On the plus side, it’s very important for IoT startups to comprehend that the foundation for a successful new product does exist. This means that experience and knowhow concerning the design, fabrication and assembly of these complex products are readily available. And the best advice is for sensible IoT product entrepreneurs and forerunners to focus on the recommendations that veteran electronics manufacturing services or EMS vendors have to offer. These corporations in addition to their engineering employees have already conducted the job with groundbreaking IoT corporations in Silicon Valley participating in the first stages of this growing segment.

The PCB of an IoT device is another beast than the traditional one, which is noticeably larger and flat. IoT devices, conversely, consist mainly of either rigid-flex or flex circuit assemblies, which include their very own categories of design layout, fabrication and assembly things to consider and technicalities.

Layout

A primary thing to consider is to search for expert designers who’ve accomplished a great deal of rigid-flex PCB designs. PCB space for an IoT device is limited. So you would like the designer to have firsthand layout practical experience to effectively design vital elements on that modest space.

At the same time, virtually all IoT units are not fixed; they incur appreciable movement and twisting. Here, the expert designer plays a vital role in determining bend ratios and lifecycle iterations as a critical part of a design. Additional vital design layout things to consider involve signal trace thickness, number of rigid and flex circuit layers, copper weight and stiffener placement. Stiffeners are widely used on flex circuits to make certain elements mounted on the flex circuit continue to be tightly in position to stop movement.

An alternative thing to consider is through-hole element placement in rigid-flex circuits. Why is that very important? The majority of IoT units are founded on surface mount device placement. Yet , there might be through-hole elements, which are usually attached to either the rigid portion or the flex part of the board. Through-hole elements are often employed to connect input/output or I/O signals to the exterior world. Doing this, those signals can be displayed having an LCD or LED monitor. Through-hole element placement is a vital account in an IoT device as when applied to the flex portion of the board, appropriate stiffeners ought to be designed and implemented for ideal assembly.

Eventually in the layout category, the heat which elements bring in should be considered. IoT units are starting to be difficult with rigid-flex and flex circuits featuring approximately 12 – 14 layers. A few units are digital. Yet , more and more analog systems are being exercised in IoT systems. Analog circuitry delivers way more heat than digital ones. This indicates heat expansion as well as contraction rate are required to be taken into consideration. In tech lingo, this is actually called the Coefficient of Thermal Expansion or CTE and the good dealing with it.

Manufacturing

Deciding on the best fabricator is essential and is linked to the EMS partner you have picked out. The fabricator you desire must have IoT PCB fabrication experience. Among vital things to consider here are insuring sturdy adhesions between layers on both rigid and flex circuit sides, learning all the vital calculations and getting a solid knowledge of when current moves from the rigid side to the flex side.

Such fabricators also needs to possess an in-depth knowledge of exceptionally small components like 0201 and also 00105 device packages, package-on-package, and the use of fine-pitch ball-grid array or BGA packaged devices.

In addition they ought to have experience in designing boards with truly tight tolerances in terms of footprint for those types of BGA devices, in terms of up-to-date capabilities like laser direct imaging for putting the solder mask on the board. They need to have laser drills for via drilling with sizes of 5 mils or under mainly because these IoT products could be so modest that a standard drill size of 5 to 8 mils may not be sufficient. They may ought to go to a 3 mil, which means that you must have an advanced laser drilling capability in-house.

In case you are placing via-in-pad, it is a easy way to take advantage of the small land that is available on the rigid-flex board, but it creates trouble for assembly. If vias aren’t entirely planar or flat in shape, it may be a difficulty throughout the assembly of those tiny BGA packaged devices. This comes about because non-planar surfaces could endanger the integrity of solder joints.

At times via in pads leave bumps in the event they’re not cleaned appropriately after positioning the vias and gold finish at the top. In the event that there are bumps, then the solder joints in the assembly for those tiny BGA balls in those IoT devices wouldn’t be a great joint. It could create spotty connections, which can be a larger issue to treat and work on. It all boils down to which EMS partner you’re using because they’re the ones who will decide on the fabrication house to make a thriving IoT product for you.

PCB Assembly

It’s vital to go to expert EMS companies that have effectively assembled IoT and wearable PCBs since they have special tooling and fixtures already obtainable, which are necessary for assembly to ensure that components are placed the right way, precisely and the printing is performed properly.

Printing can sometimes be a headache for IoT systems. If it’s a rigid-flex board, then there exists a change between thicknesses of the rigid and flex circuit portions, which suggests a special fixture is necessary to retain the complete rigid-flex board planar or entirely flat to help effective printing to become actually done.

Startups ought to be prepared to choose the ideal manufacturing partners and EMS firms. Doing this they can make sure that they’ve enough experience beforehand to get the multitude of design, fabrication and assembly details efficiently performed as they are key to a triumphant and prompt IoT product launch.

BALANCING ROBOT USING ARDUINO AND MPU6050



It a video of making of Balancing Robot Electronic part on a single PCB. This robot is been made using Arduino pro mini, MPU 6050, Motor driver IC L298D, Voltage Regulator LM7805 and some other basic electronic components.

Source

Internet of Things PCB considerations for Startups

Considering the fact that IoT appliances are so new, you would assume that getting an IoT printed circuit board (PCB) project off the ground starts by reinventing the wheel and suffering from a great deal of technical complications. This is far from the truth.
However it doesn’t imply IoT startups have a apparent path to stardom. Facing them is a number of design and manufacturing concerns which are unique to these small products. These things to consider need to be taken into consideration for the new IoT device to be successful.

On the plus side, it’s a consideration for IoT startups to know that the basic foundation for a successful cool product exists. What this means is experience and knowledge concerning the design, fabrication and assembly of these cutting-edge products are obtainable. Also, the best advice is for prudent IoT product business people and forerunners to follow the recommendations that skilled electronics manufacturing services or EMS companies provide. These companies and also their engineering employees have already completed this work with groundbreaking IoT corporations in Silicon Valley participating in the first stages of this rising industry.

The PCB of an IoT device is a special beast than the traditional one, which is much larger and flat. IoT devices, in comparison, are made up generally of either rigid-flex or flex circuit assemblies, which come with their own categories of design layout, fabrication and assembly things to consider and intricacies.

Layout

A top thing to consider is to search for skilled designers who have undertaken quite a lot of rigid-flex PCB designs. PCB space for an IoT device is tight. So you want the designer to have firsthand layout practical experience to correctly design key elements on that small space.

Besides that, most IoT gadgets are not stationary; they incur substantial movement and folding. Right here, the skilled designer plays a key role in working out bend ratios and lifecycle iterations as a important part of a design. Additional key design layout things to consider comprise signal trace thickness, number of rigid and flex circuit layers, copper weight and stiffener placement. Stiffeners are used on flex circuits to be certain that elements mounted on the flex circuit stay tightly in place to stop movement.

One additional aspect to consider is through-hole element placement in rigid-flex circuits. What makes that significant? A great deal of IoT devices are based on surface mount device placement. However , there can be through-hole elements, which are typically attached to either the rigid section or the flex portion of the board. Through-hole elements are in general useful to communicate input/output or I/O signals to the outer world. Like that, those signals can show up having an LCD or LED monitor. Through-hole element placement is a crucial thing to consider in an IoT device since when utilized on the flex part of the board, proper stiffeners ought to be designed and employed for appropriate assembly.

Then finally in the layout category, the high temperature that elements deliver is required to be deemed. IoT gadgets are increasingly challenging with rigid-flex and flex circuits featuring up to 12 to 14 layers. Several gadgets are digital. However , increasingly more analog systems are being utilized in IoT systems. Analog circuitry makes far more heat than digital ones. This suggests heat expansion and contraction rate should be considered. In tech lingo, it is known as the Coefficient of Thermal Expansion or CTE and the proper treatments for it.

Fabrication

Selecting the best fabricator is important and is linked to the EMS firm you have chosen. The fabricator you expect needs to have IoT PCB fabrication experience. Among key things to consider here are making sure robust adhesions in between layers on both rigid and flex circuit sides, understanding all the essential calculations and possessing a strong comprehension of when current moves from the rigid side to the flex side.

These fabricators also must get an in-depth know-how about tremendously tiny parts for instance 0201 and also 00105 device packages, package-on-package, and the use of fine-pitch ball-grid array or BGA packaged devices.

They also need to have knowledge of designing boards with fairly tight tolerances in terms of footprint for those types of BGA devices, in terms of up-to-date capabilities like laser direct imaging for putting the solder mask on the board. They need to have laser drills for via drilling with sizes of 5 mils or under since these IoT products could be so tiny that a common drill size of 5 to 8 mils may well not be all you need. They may require to go to a 3 mil, which means that you have to have an cutting-edge laser drilling capability on-site.

If you’re placing via-in-pad, it’s a easy way to take advantage of the small land which is available on the rigid-flex board, nevertheless , it produces difficulties for assembly. If vias are not fully planar or flat in shape, it will be hard through the assembly of those tiny BGA packaged devices. That’s because non-planar surfaces may threaten the integrity of solder joints.

At times via in pads leave bumps in cases where they’re not scoured properly after positioning the vias and gold finish at the top. When there are bumps, then the solder joints in the assembly for those tiny BGA balls in those IoT devices wouldn’t be an excellent joint. It could create spotty connections, which can be a larger issue to treat and remedy. It all boils down to which EMS firm you are using because they’re the ones who will pick the fabrication facility to make a successful IoT product for you.

PCB Assembly

It’s crucial to head off to skilled EMS companies that have effectively assembled IoT and wearable PCBs since they have specialized tooling and fixtures readily obtainable, which are essential for assembly to make sure components are placed appropriately, precisely and the printing is completed effectively.

Printing can be a problem for IoT systems. If it’s a rigid-flex board, then you can find a difference between thicknesses of the rigid and flex circuit portions, which means a special fixture is required to retain the complete rigid-flex board planar or absolutely flat to allow effective printing to be carried out.

Startups should be all set to choose the correct manufacturing partners and EMS companies. In this manner they can make sure they’ve ample experience upfront to get the multitude of design, fabrication and assembly details effectively performed since they are essential to a triumphant and timely IoT product release.

Arduino Tutorial #1 – Getting Started and Connected!



Follow this link for a Free Arduino Introductory course:
https://programmingelectronics.com/mj_lorton
——————— Click “Show more” ——————————-
Please support my content creation by using my Amazon Store:
http://astore.amazon.com/m0711-20

The first Arduino tutorial on getting started and connecting it to your PC.
Follow this link for a Free Arduino Introductory course:
https://programmingelectronics.com/mj_lorton
——————— Click “Show more” ——————————-
My website and forum:- http://www.mjlorton.com
Donations and contributions:- http://www.mjlorton.com
My techie channel MJLorton – Solar Power and Electronic Measurement Equipment – http://www.youtube.com/MJLorton
My Techie Amazon Store: http://astore.amazon.com/m0711-20
My other channel VBlogMag – For almost any topic under the sun! – http://www.youtube.com/VBlogMag
My VBlogMag Amazon Store: http://astore.amazon.com/vblogmag-20
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Arduino Site: http://www.arduino.cc/
Arduino software / IDE: http://arduino.cc/en/Main/Software
Arduino forum: http://arduino.cc/forum/

In this video I cover the following:

* What is Arduino?
* What is a sketch?
* What is the Arduino (software) IDE (interactive development environment) arduino-1.0.1
* Arduino philosophy
* We take a look at the Arduno hardware.
* I cover how to download the Arduino Software and drivers and then how to install them.
* What happens when the Arduino USB device driver fails and how to solve it.
* I upload a sketch to the Arduino UNO R3 to test it and blink an LED.
* I discuss the project for tutorial #2, a voltmeter with Min Max Ave.
* I talk about the Sparkfun serial enabled 16 x 2 LCD and the challenges it poses.

Arduino Uno R3 features:

* ATmega328 micro controller
* Input voltage – 7-12V
* 14 Digital I/O Pins (6 PWM outputs)
* 6 Analogue Inputs
* 32k Flash Memory
* 16Mhz Clock Speed

Handy websites:
http://www.toddfun.com/
http://www.arduino.cc/
http://tronixstuff.wordpress.com/
http://www.timnolan.com
http://www.timnolan.com/index.php?page=arduino-ppt-solar-charger

Source

IoT PCB considerations for Startups

As IoT products are so recent, you would believe that getting an IoT printed circuit board (PCB) project off the ground starts by reinventing the wheel and struggling with a good deal of technical headaches. That is most certainly a fallacy.
But it doesn’t imply IoT startups have a straightforward path to fame and fortune. Facing them is many design and manufacturing points to consider which are distinctive to these small products. These things to consider must be factored in for the fresh IoT device to reach their goals.

On the plus side, it’s very important for IoT startups to find out that the basic foundation for a successful awesome product exists. This suggests experience and knowledge regarding the design, fabrication and assembly of these innovative products are existing. Also, the best advice is for wise IoT product business owners and forerunners to pay attention to the recommendation that skilled electronics manufacturing services or EMS companies are offering. These businesses as well as their engineering staffs already have performed this work with groundbreaking IoT firms in Silicon Valley entering into the first stages of this surfacing industry.

The PCB of an IoT unit is a unique beast than the traditional one, which is substantially larger and flat. IoT gadgets, in comparison, comprise mostly of either rigid-flex or flex circuit assemblies, which come with their own sets of design layout, fabrication and assembly things to consider and technicalities.

Layout

A key thing to consider is to search for experienced designers who have finished loads of rigid-flex PCB designs. PCB space for an IoT unit is limited. So you want the designer to have directly layout experience to appropriately design important parts on that little space.

On top of that, most IoT units are not fixed; they get extensive movement and twisting. Here, the experienced designer plays a primary role in computing bend ratios and lifecycle iterations as a significant part of a design. Additional important design layout things to consider involve signal trace thickness, number of rigid and flex circuit layers, copper weight and stiffener placement. Stiffeners are employed on flex circuits to make certain parts connected to the flex circuit continue being tightly in place to stop movement.

An additional focus is through-hole component positioning in rigid-flex circuits. Why is that essential? Lots of IoT appliances are based on surface mount device(SMD) placement. Nevertheless , there might be through-hole parts, which are often affixed to either the rigid portion or the flex area of the board. Through-hole parts are normally useful to connect input/output or I/O signals to the exterior world. That way, those signals can be shown having an LCD or LED monitor. Through-hole component placement is an important consideration in an IoT unit simply because when attached to the flex portion of the board, proper stiffeners should be designed and employed for appropriate assembly.

Then finally in the layout category, the heat that parts deliver ought to be thought about. IoT units are becoming more sophisticated with rigid-flex and flex circuits featuring as many as 12 – 14 layers. Some units are digital. Nevertheless , gradually more analog products are being utilized in IoT products. Analog circuitry causes way more heat than digital ones. So this means heat expansion and also contraction rate should be considered. In tech lingo, it is known as the Coefficient of Thermal Expansion or CTE and the proper management of it.

Manufacturing

Selecting the most appropriate fabricator is significant and is linked to the EMS partner you have determined. The fabricator you’d like must have IoT PCB fabrication experience. Among important things to consider here are making sure effective adhesions between layers on both rigid and flex circuit sides, figuring out all of the significant calculations and possessing a great know-how about when current transfers from the rigid side to the flex side.

These fabricators also have to possess an in-depth knowledge of really miniature components like 0201 as well as 00105 device packages, package-on-package, and the employment of fine-pitch ball-grid array or BGA packaged devices.

In addition, they ought to have experience with designing boards with extremely tight tolerances in terms of footprint for those kinds of BGA devices, in terms of up-to-date capabilities like laser direct imaging for putting the solder mask on the board. They should have laser drills for via drilling with sizes of 5 mils or under since these IoT products could be so little that a normal drill size of 5 to 8 mils would possibly not be adequate. They may ought to go to a 3 mil, meaning you will need to have an superior laser drilling capability indoors.

In case you are placing via-in-pad, it is a fantastic way to make use of the small land that is available on the rigid-flex board, however , it produces trouble for assembly. If vias are not entirely planar or flat in shape, it becomes a difficulty during the assembly of those tiny BGA packaged devices. That’s because non-planar surfaces can put at risk the integrity of solder joints.

Oftentimes via in pads leave bumps in case they’re not scoured effectively after installing the vias and gold finish at the top. In cases where there are bumps, then the solder joints in the assembly for those tiny BGA balls in those IoT devices may not be an excellent joint. It might create irregular connections, which might be a larger issue to cope with and improve. It all boils down to which EMS partner you are using because they’re the ones who will select the fabrication plant to make a thriving IoT device for you.

PCB Assembly

It’s very important to head off to experienced EMS companies that have properly assembled IoT and wearable PCBs as they have special tooling and fixtures readily obtainable, which are needed for assembly to ensure that components are placed perfectly, exactly and the printing is made perfectly.

Printing is usually a issue for IoT products. If it’s a rigid-flex board, then there is a difference between thicknesses of the rigid and flex circuit portions, which implies a special fixture is needed to retain the complete rigid-flex board planar or fully flat to allow for effective printing to become attained.

Startups really should be set to choose the right manufacturing partners and EMS companies. By doing this they can make sure they have got adequate experience ahead of time to get the multitude of design, fabrication and assembly details effectively performed because they are crucial to a successful and timely IoT product launch.

New Products 11/2/2016



Othermill Pro – Compact Precision CNC + PCB Milling Machine (0:10) https://www.adafruit.com/products/2323?utm_source=youtube&utm_medium=videodescrip&utm_campaign=newproducts

Zero4U – 4 Port USB Hub for Raspberry Pi Zero v1.3 (1:23) https://www.adafruit.com/products/3298?utm_source=youtube&utm_medium=videodescrip&utm_campaign=newproducts

Mini Spy Camera With Trigger for Photo or Video (2:52) https://www.adafruit.com/products/3202?utm_source=youtube&utm_medium=videodescrip&utm_campaign=newproducts

Adafruit CP2104 Friend – USB to Serial Converter (6:50) https://www.adafruit.com/products/3309?utm_source=youtube&utm_medium=videodescrip&utm_campaign=newproducts

ESP32 WiFi-BT-BLE MCU Module / ESP-WROOM-32 (10:36) https://www.adafruit.com/products/3320?utm_source=youtube&utm_medium=videodescrip&utm_campaign=newproducts

—————————————–
Shop for all of the newest Adafruit products: http://adafru.it/new

Visit the Adafruit shop online – http://www.adafruit.com

Subscribe to Adafruit on YouTube: http://adafru.it/subscribe

Join our weekly Show & Tell on G+ Hangouts On Air: http://adafru.it/showtell

Watch our latest project videos: http://adafru.it/latest

New tutorials on the Adafruit Learning System: http://learn.adafruit.com/

Music by bartlebeats: http://soundcloud.com/bartlebeats
—————————————–

Source

IoT PCB considerations for Startups

As IoT devices are so cutting edge, you would believe that getting an IoT printed circuit board (PCB) project off the ground starts by reinventing the wheel and facing a good deal of technical complications. This is not true.
Nevertheless it doesn’t imply IoT startups have a certain way to stardom. Facing them is quite a few design and manufacturing factors to consider which are unique to these small products. These considerations are required to be considered for the fresh new IoT device to reach their goals.

On the plus side, it’s essential for IoT startups to recognise that the basic foundation for a successful cool product exists. This indicates experience and knowledge regarding the design, fabrication and assembly of such innovative products are existing. Also, the best advice is for heady IoT product enterprisers and innovators to look closely at the counsel that experienced electronics manufacturing services or EMS vendors have to give you. These businesses along with their engineering team members have previously implemented the task with revolutionary IoT businesses in Silicon Valley joining the beginning of this surfacing market.

The PCB of an IoT device is a different beast than the traditional one, which is considerably larger and flat. IoT units, on the flip side, comprise mainly of either rigid-flex or flex circuit assemblies, which come with their own groups of design layout, fabrication and assembly considerations and nuances.

Layout

A key concern is to seek out veteran designers who have accomplished many rigid-flex PCB designs. PCB space for an IoT device is confined. So you want the designer to have directly layout experience to correctly design crucial parts on that little space.

Additionally, nearly all IoT gadgets aren’t stationary; they get significant movement and folding. Right here, the veteran designer plays an important role in determining bend ratios and lifecycle iterations as a critical part of a design. Additional crucial design layout considerations incorporate signal trace thickness, number of rigid and flex circuit layers, copper weight and stiffener placement. Stiffeners are used on flex circuits to make certain parts attached with the flex circuit remain tightly in place to avoid movement.

Yet another aspect to consider is through-hole element placement in rigid-flex circuits. Why is that pretty important? Most IoT products are based on surface mount device placement. Nevertheless , there might be through-hole parts, which are commonly attached to either the rigid part or the flex part of the board. Through-hole parts are generally employed to communicate input/output or I/O signals to the outer world. Doing this, those signals can show up utilising an LCD or LED monitor. Through-hole element placement is a critical account in an IoT system as when applied on the flex area of the board, suitable stiffeners must be designed and employed for excellent assembly.

Lastly in the layout category, the heat that parts deliver ought to be deemed. IoT gadgets are ever more challenging with rigid-flex and flex circuits featuring over 12 – 14 layers. A few gadgets are digital. Nevertheless , increasingly more analog products are getting used in IoT products. Analog circuitry generates considerably more heat than digital ones. It implies heat expansion and then contraction rate are required to be thought about. In tech lingo, this is actually referred to as the Coefficient of Thermal Expansion or CTE and the right control over it.

Fabrication

Choosing the proper fabricator is very important and is linked to the EMS corporation you’ve picked. The fabricator you want should have IoT PCB fabrication practical experience. Amongst crucial considerations here are insuring strong adhesions between layers on both rigid and flex circuit sides, realizing all the crucial calculations and obtaining a strong comprehension of when current moves from the rigid side to the flex side.

Such fabricators also need to get an in-depth knowledge of very miniature parts similar to 0201 and 00105 device packages, package-on-package, and the use of fine-pitch ball-grid array or BGA packaged devices.

Additionally they must have experience of designing boards with extremely tight tolerances in terms of footprint for those sorts of BGA devices, in terms of up-to-date capabilities like laser direct imaging for putting the solder mask on the board. They ought to have laser drills for via drilling with sizes of 5 mils or under as these IoT products could be so compact that a standard drill size of 5 to 8 mils probably won’t be enough. They could require to go to a 3 mil, which means you must have an cutting-edge laser drilling capability on-site.

If you’re placing via-in-pad, it’s a great way to make use of the small land which is available on the rigid-flex board, however , it presents trouble for assembly. If vias aren’t entirely planar or flat in shape, it could be tricky throughout the assembly of those tiny BGA packaged devices. That is because non-planar surfaces might put in danger the integrity of solder joints.

At times via in pads leave bumps in the event they’re not scrubbed appropriately after positioning the vias and gold finish on the top. When there are bumps, then the solder joints in the assembly for those tiny BGA balls in those IoT devices would not be an ideal joint. It may create irregular connections, which might be a larger issue to handle and repair. It all boils down to which EMS corporation you’re working with because they’re the ones who will pick the fabrication house to make a successful IoT device for you.

PCB Assembly

It’s very important to take a look at veteran EMS companies that have efficiently assembled IoT and wearable PCBs because they have unique tooling and fixtures already existing, which are important for assembly to make sure components are placed the proper way, accurately and the printing is made in the right way.

Printing generally is a problem for IoT products. If it’s a rigid-flex board, then you will find there’s a change between thicknesses of the rigid and flex circuit portions, that means a special fixture is required to retain the complete rigid-flex board planar or absolutely flat to get effective printing to become executed.

Startups ought to be geared up to choose the proper manufacturing partners and EMS companies. This way they can make sure they have adequate experience beforehand to get the multitude of design, fabrication and assembly details successfully performed since they are crucial to a triumphant and timely IoT product release.

RPi Interactive Graphics Controller



For more details about this project, please click this link to see the full article: http://www.allaboutcircuits.com/projects/building-raspberry-pi-controllers-part-7-an-interactive-graphics-controller/

The Raspberry Pi is a versatile SBC (Single Board Computer) that allows a variety of embedded controllers to be built. The projects discussed in this hands-on series are a small example of the electronic devices and gadgets that can be built with a Raspberry Pi. For more information, as well as all the latest All About Circuits projects and articles, visit the official website at http://www.allaboutcircuits.com/

Subscribe on YouTube: https://www.youtube.com/c/AllAboutCircuitsVideo
Like us on Facebook: https://www.facebook.com/allaboutcircuits
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Contact us: http://eetech.com/

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Best Four fun projects for the Raspberry Pi Zero W

1. Make a Raspberry Pi Zero AirPlay Speaker

While this project in the beginning demands using a Raspberry Pi Zero with a WiFi dongle add-on, the Zero W fully eradicates the necessity for this add-on. Together with a low priced 5V easily portable battery, it is simple to build yourself a amazing, wireless AirPlay speaker for streaming music from your Apple device.

Check out the whole step-by-step from Hackster. https://www.hackster.io/fvdbosch/raspberry-pi-zero-airplay-speaker-d99feb

2. Make a Raspberry Pi Zero W desk clock

As a result of Pi Zero W’s wireless capabilities, anybody can build yourself a desktop clock that’s accurate to within just a few milliseconds. Once you have all the parts (with a display that looks straight out of a Hollywood thriller), it is possible to hook up the clock via WiFi to the Network Time Protocol (NTP) and sleep nicely knowing you are in sync with the rest of the world.

Look at the whole step-by-step suggestions on Hackaday. https://hackaday.io/post/54276

3. Create your personal Raspberry Pi-powered R2-D2

For those who have always wanted to hack a toy R2-D2 into something a bit more reasonable, the Raspberry Pi Zero W has arrived to collaborate. Les Pounder from TechRadar has shared a instruction for adding some wheels and attitude to the precious robot from the “Star Wars” world.

Check out the step-by-step manuals right here. http://www.techradar.com/how-to/computing/how-to-build-your-own-r2-d2-with-the-raspberry-pi-zero-1310979

4. A Pi Zero W security camera

One of the several large distinct benefits to using a Raspberry Pi Zero W is its capacity to remain connected to the internet in places with no ethernet connection. For security camera products, this new addition is amazingly advantageous.

Over at Raspberry Pi Spy, finely detailed guidelines have already been shared to creating your very own Pi Zero W security camera. Better yet, there already exists both a good way to mount your camera and a dedicated OS known as motionEyeOS to tie it as a whole.

Check out the whole step-by-step here. http://www.raspberrypi-spy.co.uk/2017/04/raspberry-pi-zero-w-cctv-camera-with-motioneyeos

Postbag: #24 – 555 Timers, MP3 Player, 150mAh Lipo, Proto PCBs



What’s in today’s post?

NE555 Duty Cycle and Frequency Adjustable Module Square Wave rectangular wave http://www.ebay.co.uk/itm/-/310702401768

NE555 Pulse Module LM358 Duty Cycle Frequency Adjustable Module Square Wave http://www.ebay.co.uk/itm/-/310703064800

NE555 DC 12V Delay relay shield Timer Switch Adjustable Module 0 to 10 Second http://www.ebay.co.uk/itm/-/310979634874

USB Mini Clip MP3 Player Screen Support LCD Up To 16GB Micro SD TF Card 5 Colors http://www.ebay.co.uk/itm/-/371151312150

Red Universal Car Windshield Stand Mount Holder For PDA iPod Cell Phone GPS New http://www.ebay.co.uk/itm/-/371144309750

10 Pcs 2cm x 8cm FR-4 Two Sided Prototype DIY Universal PCB Print Circuit Board http://www.ebay.co.uk/itm/-/191241792438

8PCS Double Side Prototype PCB Tinned breadBoard 5×7 4×6 3×7 2x8CM Each 2Pcs FR4 http://www.ebay.co.uk/itm/8PCS-Double-Side-Prototype-PCB-Tinned-breadBoard-5×7-4×6-3×7-2x8CM-Each-2Pcs-FR4-/310910403198

Source

IoT PCB ways to care for Startups

Considering IoT products are so cutting edge, you would consider that getting an IoT printed circuit board (PCB) project off the ground starts by reinventing the wheel and experiencing a wide range of technical problem. That is most certainly a misconception.
Nonetheless it doesn’t indicate IoT startups have a certain route to fame and fortune. Facing them is quite a lot of design and manufacturing factors to consider which are completely unique to these small products. These points need to be taken into account for the fresh IoT device to succeed.

On the plus side, it’s a consideration for IoT startups to be aware of that the foundation for a successful new product does exist. This means experience and knowhow involving the design, fabrication and assembly of these kinds of cutting-edge products are accessible. Also, the best advice is for wise IoT product business owners and creators to follow the recommendations that veteran electronics manufacturing services or EMS suppliers have to give. These firms in addition to their engineering employees have performed the work with groundbreaking IoT firms in Silicon Valley participating in the early stages of this promising sector.

The PCB of an IoT unit is a distinct beast than the traditional one, which is notably larger and flat. IoT units, in comparison, comprise largely of either rigid-flex or flex circuit assemblies, which include their very own categories of design layout, fabrication and assembly points and technicalities.

Layout

A key factor is to try to find seasoned designers who have completed many rigid-flex PCB designs. PCB space for an IoT unit is scarce. So you want the designer to have firsthand layout experience to correctly design significant components on that compact room.

At the same time, nearly all IoT devices aren’t fixed; they bring significant movement and twisting. Right here, the seasoned designer plays a vital role in figuring out bend ratios and lifecycle iterations as a serious part of a design. Some other significant design layout points include signal trace thickness, number of rigid and flex circuit layers, copper weight and stiffener placement. Stiffeners are used on flex circuits to ensure that components attached with the flex circuit continue being tightly in place to prevent itself from movement.

An additional aspect to consider is through-hole element placement in rigid-flex circuits. How come is that significant? Most of the IoT devices are based on surface mount device placement. However , there could be through-hole components, which are often positioned on either the rigid part or the flex area of the board. Through-hole components are generally utilized to communicate input/output or I/O signals to the outside world. Like that, those signals can be displayed by using an LCD or LED monitor. Through-hole element placement is a key thing to consider in an IoT unit because when applied to the flex section of the board, right stiffeners need to be designed and employed for appropriate assembly.

Lastly in the layout category, the heat that components bring in must be evaluated. IoT devices are ever more difficult with rigid-flex and flex circuits featuring up to 12 – 14 layers. A few devices are digital. However , gradually more analog systems are getting used in IoT systems. Analog circuitry results in a great deal more heat than digital ones. That means heat expansion plus contraction rate ought to be factored in. In tech lingo, this is actually referred to as the Coefficient of Thermal Expansion or CTE and the right dealing with it.

Manufacturing

Finding the right fabricator is critical and is linked to the EMS company you’ve selected. The fabricator you are looking for needs to have IoT PCB fabrication experience. Among significant points here are ensuring strong adhesions between layers on both rigid and flex circuit sides, being aware of all of the important calculations and having a good know-how about when current moves from the rigid side to the flex side.

Such fabricators also have to possess an in-depth comprehension of exceptionally modest components such as 0201 and 00105 device packages, package-on-package, and the use of fine-pitch ball-grid array or BGA packaged devices.

In addition they should have experience of designing boards with fairly tight tolerances in terms of footprint for those types of BGA devices, in terms of up-to-date capabilities like laser direct imaging for putting the solder mask on the board. They must have laser drills for via drilling with sizes of 5 mils or under since these IoT products could be so small that a standard drill size of 5 to 8 mils might not be sufficient. They could need to go to a 3 mil, which indicates that you should get an excellent laser drilling capability indoors.

In the event that you’re placing via-in-pad, it’s really a great way to utilize the small space that is available on the rigid-flex board, however , it poses trouble for assembly. If vias are not totally planar or flat in shape, it will become tricky over the assembly of those tiny BGA packaged devices. That’s because non-planar surfaces can easily threaten the integrity of solder joints.

At times via in pads leave bumps in the event they’re not scrubbed appropriately after positioning the vias and gold finish on top. In case there are bumps, then the solder joints in the assembly for those tiny BGA balls in those IoT devices would not be an ideal joint. This might create occasional connections, which might be a bigger issue to cope with and fix. It all boils down to which EMS company you’re working with because they’re the ones who will decide on the fabrication house to make a triumphant IoT item for you.

PCB Assembly

It’s very important to head off to seasoned EMS companies that have effectively assembled IoT and wearable PCBs because they have specialized tooling and fixtures readily available, which are needed for assembly to make certain that components are placed appropriately, accurately and the printing is practiced appropriately.

Printing generally is a problem for IoT systems. If it’s a rigid-flex board, then there does exist a difference between thicknesses of the rigid and flex circuit portions, which suggests a special fixture is needed to retain the complete rigid-flex board planar or thoroughly flat to allow effective printing to become accomplished.

Startups need to be prepared to choose the correct manufacturing partners and EMS corporations. This way they can be certain they have got sufficient experience before hand to get the multitude of design, fabrication and assembly details successfully performed as they are crucial to a thriving and timely IoT product release.

Raspberry Pi 3 Emulator Testing with Tony D! #gaming #retro @adafruit #LIVE



Live stream to http://twitch.tv/adafruit testing the performance of various video game system emulators on the new Raspberry Pi 3. The latest 3.6 version of Retropie is used to run the emulators, and the following systems are tested (with time codes into the video to jump right to them):
– NES: ~3:25 https://youtu.be/5baYAlWZs24?t=205
– Gameboy: ~8:34 https://youtu.be/5baYAlWZs24?t=514
– SNES: ~11:23 https://youtu.be/5baYAlWZs24?t=683
– Genesis: ~20:54 https://youtu.be/5baYAlWZs24?t=1254
– Gameboy Advance: 24:32 https://youtu.be/5baYAlWZs24?t=1472
– Nintendo 64: ~28:13 https://youtu.be/5baYAlWZs24?t=1693
– Playstation: ~33:39 https://youtu.be/5baYAlWZs24?t=2019
– Saturn: ~41:16 https://youtu.be/5baYAlWZs24?t=2476
– Dreamcast: ~42:17 https://youtu.be/5baYAlWZs24?t=2537
– Playstation Portable: ~45:23 https://youtu.be/5baYAlWZs24?t=2723

Note shown but attempted to play without success:
– Nintendo DS: Couldn’t get games to load.
– Sega CD: Couldn’t get games to load.

Check out Retropie at: http://blog.petrockblock.com/retropie/

—————————————–
Visit the Adafruit shop online – http://www.adafruit.com

Subscribe to Adafruit on YouTube: http://adafru.it/subscribe

Join our weekly Show & Tell on G+ Hangouts On Air: http://adafru.it/showtell

Watch our latest project videos: http://adafru.it/latest

New tutorials on the Adafruit Learning System: http://learn.adafruit.com/

Music by bartlebeats: http://soundcloud.com/bartlebeats
—————————————–

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One-upping the NES Classic Edition with the Raspberry Pi 3 and RetroPie

NES Classic is no more, but luckily economical hobbyist boards are great for little projects.

Last Nov., Nintendo shocked everyone by going back to its root base and releasing the NES Classic. The pleasing emulator/nostalgia-fest started unexpected demand, including near-instant supply issues and 200-percent-plus markups in secondary markets. So in December of 2016, we made a decision to build our own version instead. Since Nintendo bizarrely announced that it won’t be making any more of the hard-to-find mini consoles recently, we’re re-running this piece to help people with a DIY streak again build your own. Hardware recommendations have been updated to reflect current availability and pricing for April 2017.

Find out more https://arstechnica.com/gaming/2017/04/one-upping-the-nes-classic-edition-with-the-raspberry-pi-3-and-retropie/

Meet MintyPi 2.0: Raspberry Pi Video Gaming Emulator Jam-packed Into Tiny Mint Tin Box

A YouTuber and innovator has shared mintyPi 2.0, a project that changes a typical mint tin box into a transportable video gaming console.

MintyPi 2.0, powered by the Raspberry Pi small computer, is the second attempt at the project, bringing with it a range of betterments as compared to the original mintyPi.

Find out more http://www.techtimes.com/articles/204662/20170411/meet-mintypi-2-0-raspberry-pi-video-game-emulator-packed-into-tiny-mint-tin-box.htm

JB Hi-Fi Just Received The Mother Lode Of Nintendo Classic Minis

Christmas 2016 will forever be valued as the year people went legit bananas for a retro NES console. The thing was a piece of plastic that just played 30 games from the 8-bit era – but nostalgia is a ultra powerful thing. So powerful that demand completely exceeded supply, ultimately causing crashed websites, exhausted stock and a large number of empty-handed clients.

For people still on a Zelda-like quest to obtain this mythical product, we have some nice thing about it: the Nintendo NES Classic Edition is right now for sale in JB Hi-FI stores, Throughout australia. Hurrah!

Find out more at https://www.lifehacker.com.au/2017/04/jb-hi-fi-just-received-a-butt-load-of-nintendo-mini-nes-consoles/

CHIP Computer Project: CPU Temperature Monitor with OLED display SSD1306



Today we are going to connect an OLED display to the chip computer (often called the $9 computer) in order to monitor its CPU temperature in real time. Let’s start!

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WHERE TO BUY
——————–

CHIP Computer: https://getchip.com/pages/chip

OLED display: http://bit.ly/OLED_DISPLAY

Xiaomi Powerbank: http://bit.ly/PowerBank_XiaoMi

Wires: http://bit.ly/Wires3InOne

Full disclosure: Some of the links above are affiliate links. I get a small percentage of each sale they generate. Thank you for your support!

Today’s project is this: I have connected an I2C OLED display to the CHIP single board computer and I print the temperature of the CPU on it in real time! It is a very easy project to build and it can be easily ported to support the Raspberry Pi as well. Let’s see how to build this project.

I received the CHIP single board computer about a year ago. It is an impressive board, it costs $9 and it offers a 1GHz CPU, 256MB of RAM wifi Bluetooth and many more things. You can watch my review of the CHIP computer by clicking on the card here. As you can see the CHIP computer is a lot smaller than the Raspberry Pi 3 board and of course it costs a lot less. One year later, the software developed for the CHIP computer is mature and we can easily build some projects with it.

For this project we also use this small monochrome OLED display. It is one of my favorite displays because it is very easy to use since it use the I2C interface which only needs to connect two wires. The cost of this display is around $6. You can find links for both parts in the description of the video.

In order to connect the OLED display to the CHIP computer we only have to connect 4 wires. The GND pin of the display goes GND, Vcc goes to the 3.3V output of the display, SCL pin of the display goes to the SCK pin of the CHIP computer and lastly the SDA pin of the display goes to the SDA pin of the CHIP computer. It is very nice to have the pins labeled on the CHIP computer isn’t it? It makes things easier. Maybe the Raspberry Pi needs to follow the same tactic with their boards. Now, let’s move on the software side of the project.

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LIBRARIES
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CHIP_IO: https://github.com/xtacocorex/CHIP_IO

Adafruit_Python_GPIO: https://github.com/xtacocorex/Adafruit_Python_GPIO

rm-hull SSD1306: https://github.com/rm-hull/ssd1306

——————–
CODE OF THE PROJECT
——————–

CHIP Computer Project: CPU Monitor

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Physics Experiments Puzzle Game
——————–

You can download my latest Android Game which is called Incredible Physics Experiments here:

? http://bit.ly/IncredibleExperiments

——————–
MORE PROJECTS
——————–
Arduino Datalogger: https://www.youtube.com/watch?v=oei3Y6tOhVI
Arduino Weather Station Project: https://www.youtube.com/watch?v=9jN-3DtS1RI
Arduino Nokia 5110 LCD Display: https://www.youtube.com/watch?v=aDwrMeu4k9Y
Arduino OLED display tutorial: https://www.youtube.com/watch?v=A9EwJ7M7OsI
DIY Arduino: https://www.youtube.com/watch?v=npc3uzEVvc0

——————–
ABOUT EDUC8S.TV
——————–
Educ8s.tv is a Youtube channel and website which is dedicated in developing high quality videos about DIY hardware and software projects. In this channel we develop projects with Arduino, Raspberry Pi, we build robots and simple electronic circuits. Check out our website as well for more information: http://www.educ8s.tv

——————–
SUBSCRIBE ON YOUTUBE
——————–

Never miss a video: https://www.youtube.com/subscription_center?add_user=educ8s ——————–
Physics Experiments Puzzle Game
——————–

You can download my latest Android Game which is called Incredible Physics Experiments here:

? http://bit.ly/IncredibleExperiments

——————–
MORE PROJECTS
——————–
Arduino Datalogger: https://www.youtube.com/watch?v=oei3Y6tOhVI
Arduino Weather Station Project: https://www.youtube.com/watch?v=9jN-3DtS1RI
Arduino Nokia 5110 LCD Display: https://www.youtube.com/watch?v=aDwrMeu4k9Y
Arduino OLED display tutorial: https://www.youtube.com/watch?v=A9EwJ7M7OsI
DIY Arduino: https://www.youtube.com/watch?v=npc3uzEVvc0

——————–
ABOUT EDUC8S.TV
——————–
Educ8s.tv is a Youtube channel and website which is dedicated in developing high quality videos about DIY hardware and software projects. In this channel we develop projects with Arduino, Raspberry Pi, we build robots and simple electronic circuits. Check out our website as well for more information: http://www.educ8s.tv

——————–
SUBSCRIBE ON YOUTUBE
——————–

Never miss a video: https://www.youtube.com/subscription_center?add_user=educ8s

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Best 4 exciting projects for the Raspberry Pi Zero W

1. Make a Raspberry Pi Zero AirPlay Speaker

While this project at first calls for using a Raspberry Pi Zero with a WiFi dongle accessory, the Zero W effectively eradicates the necessity for this item. Coupled with an economical 5V small battery, you can certainly build yourself a wonderful, wireless AirPlay speaker for streaming music from your Apple product.

Investigate the whole step-by-step from Hackster. https://www.hackster.io/fvdbosch/raspberry-pi-zero-airplay-speaker-d99feb

2. Make a Raspberry Pi Zero W desk clock

Due to the Pi Zero W’s wireless functions, it’s easy to build yourself a desktop clock that’s accurate to within a couple of milliseconds. Once you have all the parts (with a display that looks straight out of a Hollywood thriller), you can hook up the clock via WiFi to the Network Time Protocol (NTP) and rest well realizing you are in sync with the rest of the planet.

Look at the whole step-by-step suggestions on Hackaday. https://hackaday.io/post/54276

3. Build your personal Raspberry Pi-powered R2-D2

For those who have always wanted to hack a toy R2-D2 into something a bit more sensible, the Raspberry Pi Zero W is here now to oblige. Les Pounder from TechRadar has shared a tutorial for adding some wheels and attitude to the favorite android from the “Star Wars” universe.

Browse the step-by-step guidelines right here. http://www.techradar.com/how-to/computing/how-to-build-your-own-r2-d2-with-the-raspberry-pi-zero-1310979

4. A Pi Zero W wireless security camera

One of the several great clear advantages to having a Raspberry Pi Zero W is its capability to remain connected to the online world in places with no ethernet connection. For wireless security camera systems, this new improvement is especially advantageous.

Over at Raspberry Pi Spy, in depth guidelines have been shared to putting together your very own Pi Zero W wireless security camera. Better still, there presently exists both a good way to mount your camera and a devoted operating system referred to as motionEyeOS to tie it in its entirety.

Browse the whole step-by-step here. http://www.raspberrypi-spy.co.uk/2017/04/raspberry-pi-zero-w-cctv-camera-with-motioneyeos

Raspberry Pi Zero Internet Radio – NPR One Demo



Demo of the Raspberry Pi Zero Internet Radio using capacitive touch controls with the Adafruit MPR121 capacitive touch sensor.

The Pi Zero connects to the NPR One API and streams audio via WiFi. The Adafruit MAX98357 connects over I2S to give the Raspberry Pi Zero analog audio out.

Parts used in project:
https://www.adafruit.com/wishlists/402061

3D Printed Parts:
https://www.youmagine.com/designs/raspberry-pi-zero-npr-one-radio

A360 Design Source:
http://a360.co/1TJcnvT

Learning guide:
https://learn.adafruit.com/raspberry-pi-zero-npr-one-radio/overview

Code on Github:
https://github.com/adafruit/nprone-cli

Project by Todd Treece
http://instagram.com/uniontownlabs

The NPR logo is a registered trademark of NPR used with permission from NPR. All rights reserved.

—————————————–
Visit the Adafruit shop online – http://www.adafruit.com

Subscribe to Adafruit on YouTube: http://adafru.it/subscribe

Join our weekly Show & Tell on G+ Hangouts On Air: http://adafru.it/showtell

Watch our latest project videos: http://adafru.it/latest

New tutorials on the Adafruit Learning System: http://learn.adafruit.com/

Music by bartlebeats: http://soundcloud.com/bartlebeats
—————————————–

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Similar Content

The Raspberry Pi Zero W Brings Wi-Fi and Bluetooth to the Zero, Charging $10
http://lifehacker.com/the-raspberry-pi-zero-wireless-adds-wi-fi-and-bluetooth-1792789503

Hands-On: A case for the Raspberry Pi Zero with digicam
http://www.zdnet.com/article/hands-on-a-case-for-the-raspberry-pi-zero-with-camera/

Pack a Raspberry Zero and Display Screen Into an Altoids Container for a Lightweight Micro PC
http://lifehacker.com/cram-a-raspberry-zero-and-screen-into-an-altoids-tin-fo-1792394348

Best Five Raspberry Pi Zero Electronic Projects Which Take Advantage Of Its Small Measurement

The Raspberry Pi is definitely the hobbyist choice for Build-it-yourself electronic projects. The Raspberry Pi Zero, that’s about the size of a stick of chewing gum, is pretty cheap and has it’s own special use instances though. The following are 10 of our most liked projects that benefit from its measurement.

1. Stuff a Raspberry Pi Zero In an Old School Controller

It is well known the Raspberry Pi makes an superb DIY video gaming console. The setup process simply necessitates a couple of minutes, and the Raspberry Pi Zero is utterly able of taking on outdated games from the Super NES period and earlier. The complete project is better yet when the whole system is in a controller.

Just to illustrate (ahem), this project relies on a Super NES controller, this one tackles the NES controller, and this one uses that good old original Xbox controller. However you want to practice it, you will get a pretty slick tiny DIY retro game console you may tote around wherever.

2. Construct a Miniature Dongle PC

While the Pi Zero makes a great tiny computer as it is, it makes a better dongle computer. Doing this, you can attach it to another computer you have, then it will tether itself directly so you won’t need to include a USB or any networking.

The great thing of this project is the fact that you will not need yet another mouse, screen, or key pad hanging out around. Merely jam in into your normal computer and you’re good to go.

3. Construct the Planet’s Smallest (Potentially) MAME Cabinet

MAME cabinets are remarkable, however, they are sizeable. For the complete opposite approach, you may use a Raspberry Pi Zero to make one which is about as small as the Pi itself.

You need a few elements to make this sucker function, for instance a 3D printed case, but in the end cabinet is definitely functional, which implies you will have the best desk add-on in the workplace.

4. Build a Motion Sensing Digicam


source: http://www.instructables.com/id/Raspberry-Pi-Motion-Sensing-Camera/

The Raspberry Pi is actually an incredible motion sensing digicam, but the low profile of the Pi Zero helps make it a lot better.

Employing the Raspberry Pi Zero, your motion sensing camera has a quite smaller foot print, meaning it can go in even tighter spaces. For illustration, this one mounts to your window with a couple of suction cups, which is about as lightweight as it may get.

5. Play Any Simpsons Episode (or maybe Any Television Program) At Random

If you have ditched cable and gone full streaming with your media, you might still miss the days of catching a random episode of your favorite TV show. The Raspberry Pi Zero may bring that back.

In this project, they use installments of The Simpsons placed on an Sdcard. With a custom script, it’s possible to click on a control button and it plays an episode arbitrarily. You’re able to increase any media you prefer here, including many different shows if you wished, yet, The Simpsons make the perfect option.

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