This breadboard will allow prototyping of projects prior to a more permanent assembly solution its ideal for hobbyists students Lab work or by any one who needs to test a circuit. A self-adhesive pad is attached to the rear of the breadboard. Can also be connected to AD-01BZ13P AD-100AG08J AD-102AG10L or other AD-101 blocks.

Dimensions 83x 52x 10mm.

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This breadboard will allow prototyping of projects prior to a more permanent assembly solution, it's ideal for hobbyists, students, Lab work or by any one who needs to test a circuit. A self-adhesive pad is attached to the rear of the breadboard. Can also be connected to AD-01 (BZ13P), AD-100 (AG08J), AD-101 (AG09K), or other AD-102 blocks. Dimensions: 62x 83x 10mm. ...

This breadboard will allow prototyping of projects prior to a more permanent assembly solution its ideal for hobbyists students Lab work or by any one who needs to test a circuit. A self-adhesive pad is attached to the rear of the breadboard. Can also be connected to AD-01BZ13P AD-100AG08J AD-101AG09K or other AD-102 blocks.

Dimensions 62x 83x 10mm.

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A range of solderless breadboard modules that can interconnect to suit individual requirements. The basic board AD-01 consists of four blocks of six columns of 28 rows, the sockets in each row being interconnected. The blocks are a standard DIP size apart, although MSI & LSI type chips can be used. At both ends of the blocks, there are two power busses. The ‘ Red’ bus is made up of two separate rows of 12 connecting sockets, & the ‘ Black’ bus is one row of 24 connecting sockets There is an additional matrix of 30 by 6 sockets for non-dip type components. The six sockets in the vertical plane are interconnected. Each socket will accept solid wire from 20 to 30 swg (0•3 to 0•8mm). The base has a ‘sticky’ covering to hold the board firm on a workbench or surface. The AD-10 power block has 5 individual screw terminals that will accept 4•5mm Y-terminal, stripped wire or 4mm banana plug. Each terminal is connected to two sockets. The power block will snap lock onto the AD-01 base board to allow connections to the required power bus. The power block has the same ‘sticky’ base. After use the modules can be unlocked & remade into a different configuration.AD-11 is one AD-01 & one AD-10.

Size: 147 x 80mm

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A range of solderless breadboard modules that can interconnect to suit individual requirements. The basic board AD-01 consists of four blocks of six columns of 28 rows, the sockets in each row being interconnected. The blocks are a standard DIP size apart, although MSI & LSI type chips can be used. At both ends of the blocks, there are two power busses. The ‘ Red’ bus is made up of two separate rows of 12 connecting sockets, & the ‘ Black’ bus is one row of 24 connecting sockets There is an additional matrix of 30 by 6 sockets for non-dip type components. The six sockets in the vertical plane are interconnected. Each socket will accept solid wire from 20 to 30 swg (0•3 to 0•8mm). The base has a ‘sticky’ covering to hold the board firm on a workbench or surface. The AD-10 power block has 5 individual screw terminals that will accept 4•5mm Y-terminal, stripped wire or 4mm banana plug. Each terminal is connected to two sockets. The power block will snap lock onto the AD-01 base board to allow connections to the required power bus. The power block has the same ‘sticky’ base. After use the modules can be unlocked & remade into a different configuration.AD-14 is four AD-01 & one AD-10 mounted on a blue base board.

Size: 335 x 168mm

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• Requires a 5V supply• Constant current drivers for ultra-bright, consistent colour•1/16 step display dimming•I2C interface• Backpack comes with address-selection jumpers so you can connect up to four mini 8x 8's or eight 7-segments • And to view the library please click here to help you get started!• To see Adafruits tutorial showing how to solder, wire & control the display please click here What's better than a single LED? Lots of LEDs! A fun way to make a small display is to use an 8x 8 matrix or a 4-digit 7-segment display. Matrices like these are 'multiplexed'
- so to control 64 LEDs you need 16 pins. That's a lot of pins, & there are driver chips like the MAX7219 that can control a matrix for you but there's a lot of wiring to set up & they take up a ton of space. The matrices use a driver chip that does all the heavy lifting for you: They have a built in clock so they multiplex the display. They use constant-current drivers for ultra-bright, consistent colour (the images above are photographed at the dimmest setting to avoid overloading our camera!), 1/16 step display dimming, all via a simple I2C interface. These 1.2" matrix backpacks come with three address-selection jumpers so you can connect up to eight 1.2" 8x 8's together (or a combination, such as four 1.2" 8x 8's & four 7-segments, etc) on a single I2C bus.
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• Requires a 5V supply• Constant current drivers for ultra-bright, consistent colour•1/16 step display dimming•I2C interface• Backpack comes with address-selection jumpers so you can connect up to four mini 8x 8's or eight 7-segments • And to view the library please click here to help you get started!• To see Adafruits tutorial showing how to solder, wire & control the display please click here What's better than a single LED? Lots of LEDs! A fun way to make a small display is to use an 8x 8 matrix or a 4-digit 7-segment display. Matrices like these are 'multiplexed'
- so to control 64 LEDs you need 16 pins. That's a lot of pins, & there are driver chips like the MAX7219 that can control a matrix for you but there's a lot of wiring to set up & they take up a ton of space. The matrices use a driver chip that does all the heavy lifting for you: They have a built in clock so they multiplex the display. They use constant-current drivers for ultra-bright, consistent colour (the images above are photographed at the dimmest setting to avoid overloading our camera!), 1/16 step display dimming, all via a simple I2C interface. These 1.2" matrix backpacks come with three address-selection jumpers so you can connect up to eight 1.2" 8x 8's together (or a combination, such as four 1.2" 8x 8's & four 7-segments, etc) on a single I2C bus.
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• Requires a 5V supply• Constant current drivers for ultra-bright, consistent colour•1/16 step display dimming•I2C interface• Backpack comes with address-selection jumpers so you can connect up to four mini 8x 8's or eight 7-segments • And to view the library please click here to help you get started!• To see Adafruits tutorial showing how to solder, wire & control the display please click here What's better than a single LED? Lots of LEDs! A fun way to make a small display is to use an 8x 8 matrix or a 4-digit 7-segment display. Matrices like these are 'multiplexed'
- so to control 64 LEDs you need 16 pins. That's a lot of pins, & there are driver chips like the MAX7219 that can control a matrix for you but there's a lot of wiring to set up & they take up a ton of space. The matrices use a driver chip that does all the heavy lifting for you: They have a built in clock so they multiplex the display. They use constant-current drivers for ultra-bright, consistent colour (the images above are photographed at the dimmest setting to avoid overloading our camera!), 1/16 step display dimming, all via a simple I2C interface. These 1.2" matrix backpacks come with three address-selection jumpers so you can connect up to eight 1.2" 8x 8's together (or a combination, such as four 1.2" 8x 8's & four 7-segments, etc) on a single I2C bus.
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• Requires a 5V supply• Constant current drivers for ultra-bright, consistent colour•1/16 step display dimming•I2C interface• Backpack comes with address-selection jumpers so you can connect up to four mini 8x 8's or eight 7-segments • And to view the library please click here to help you get started!• To see Adafruits tutorial showing how to solder, wire & control the display please click here What's better than a single LED? Lots of LEDs! A fun way to make a small display is to use an 8x 8 matrix or a 4-digit 7-segment display. Matrices like these are 'multiplexed'
- so to control 64 LEDs you need 16 pins. That's a lot of pins, & there are driver chips like the MAX7219 that can control a matrix for you but there's a lot of wiring to set up & they take up a ton of space. The matrices use a driver chip that does all the heavy lifting for you: They have a built in clock so they multiplex the display. They use constant-current drivers for ultra-bright, consistent colour (the images above are photographed at the dimmest setting to avoid overloading our camera!), 1/16 step display dimming, all via a simple I2C interface. These 1.2" matrix backpacks come with three address-selection jumpers so you can connect up to eight 1.2" 8x 8's together (or a combination, such as four 1.2" 8x 8's & four 7-segments, etc) on a single I2C bus.
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•1.8"" diagonal TFT display with 128x 160 colour pixels can display full 18-bit colour• Ultra-low-dropout 3.3V regulator & a 3/5V level shifter built in so its safe to use with 5V Arduinos• Micro SD card holder
- you can easily load full colour bitmaps from a FAT16/FAT32 formatted micro SD card (not included)•5 way navigation switch
- up, down, left, right, select• If you'd like to add the navigation switch, it uses Analog 3•2 white LED backlight, transistor connected• Defaults to 'on' but can be connected to a digital pin for PWM or simply turning off• Comes with header, requires soldering!• Click here to see the detailed tutorial guide• To see the Controller/ Driver datasheet please click here• To see the Display datasheet please click here This lovely little shield is the best way to add a small, colourful & bright display to any project. We took our popular 1.8" TFT breakout board & remixed it into an Arduino shield complete with micro SD card slot & a 5-way joystick navigation switch (with a nice plastic knob)! Since the display uses only 4 pins to communicate & has its own pixel-addressable frame buffer, it can be used easily to add a display & interface without exhausting the memory or pins. The 1.8" display has 128x 160 colour pixels. Unlike the low cost " Nokia 6110" & similar LCD displays, which are CSTN type & thus have poor colour & slow refresh, this display is a true TFT! The TFT driver (ST7735R) can display full 18-bit colour (262, 144 shades!). & the LCD will always come with the same driver chip so there's no worries that your code will not work from one to the other. The shield has the TFT display soldered on (it uses a delicate flex-circuit connector) as well as a ultra-low-dropout 3.3V regulator & a 3/5V level shifter so its safe to use with 5V Arduinos. We also had some space left over so we placed a micro SD card holder (so you can easily load full colour bitmaps from a FAT16/FAT32 formatted micro SD card) & a 5-way navigation switch (left, right, up, down, select). If you just want to display text, shapes, lines, pixels, etc the shield uses pins 13, 11, 10 & 8. If you'd like to add the navigation switch, it uses Analogue 3 (all 5 switches are connected using a clever resistor trick to permit all the switches to share one analogue pin). For the micro SD card, you'll also give up Digital 12 & 4. Comes as a fully assembled & tested shield with the display, micro SD card holder & nav switch with knob as well as a stick of 0.1" header. To finish up & use, you will need to solder on the header onto the shield PCB, a quick 10 minute task.

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