Difference between revisions of "LED Bandwidth Monitor"
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== Bandwidth Monitor == | == Bandwidth Monitor == | ||
The data is feed from the gateway using the [http://www.kernel.org/pub/software/web/bwbar/ bwbar utility] for Linux. It outputs a text file every other second | The data used to change the LED-strip is feed from the gateway using the [http://www.kernel.org/pub/software/web/bwbar/ bwbar utility] for Linux. It outputs a text file every other second containing the current bandwidth utilization on the inbound and outbound interface. This text file is picked up by a shell script (sh), parsed, percentage of the maximum speed (9500kbit/s) is calculated and put in two variables. Last, the values are then passed over the network to an Arduino with an ethernet-shield using the wget utility. | ||
A simple GET-http request | A simple GET-http request containing the values as parameters, e.g. http://192.168.233.177/?up=6&dn=30, is sent to a basic webserver listening on the first Arduino. Once the values are received by the microcontroller, they're parsed to integers and transferred over a I2C/TWI-bus to the second LED-driving Arduino. | ||
The second Arduino is the LED driver and is responsible for driving the strip. It had to be on a separate device because the ethernet-shield requires SPI, as does the LED strip, and there's only one hardware SPI interface. It might be possible to put everything on one device and address ethernet | The second Arduino is the LED-driver and is responsible for updating and driving the strip. It had to be on a separate device because the ethernet-shield requires SPI, as does the LED strip, and there's only one hardware SPI-interface. It might be possible to put everything on one device and address ethernet/strip when needed, but I decided it was too time consuming to look into at the moment. The update rate of the LED strip could also suffer (as the 3 LED colors are controlled/dimmed by PWM). | ||
To drive 128 LEDs without flickering due to low update frequency or spaz out due too overlapping frequency in the shift-register. There is a lot of details on the HL1606 in the Arduino-lib examples by Adafruit. | |||
Download the shell script: | |||
* Download monitor update script | |||
Download the Arduino source code: | Download the Arduino source code: |
Revision as of 18:03, 11 January 2011
After discovering how cool RGB LED strips are, I decided to make a bandwidth monitor for the Internet connection at our place. Since there are many users active on the same connection there's bound to be conflicts where someone is gaming and another is downloading, causing the ping to fluctuate (even with QoS HTB-init set up).
I discovered the strips over at the Adafruit blog, check this Adafruit Ask an Engineer video (starting at 3:23) for details.
LED Strips
One meter of LED strip has 32 LEDs, where each section is 2.5 inch (6.35 cm) and consists of one shift-register IC, controlling two LEDS. There is also a bypass capacitor for the IC and current-limiting resistors for the LEDs. Each RGB LED has 6 pins, grouped in pairs for each of the 3 primary colors, this allows resistors to be connected fore or aft. One reel is 5 meters and comes with end-connectors already soldered on.
The strip is housed in a rubber casing and when the ends are sealed can be made semi-waterproof.
Controlling
File:LED Bandwidth Monitor hl1606.jpg
The shift-register is a HL1606 with two channels (A and B), fading capability (not used here), powered by 5V, SPI-like protocol.
Adafruit has two Arduino libraries up, one plain and one using PWM. The latter allows dimming of the three primary colors to display 3, 4, or 5-bit color.
- Adafruit HL1606 LED Strip - Arduino lib
- Adafruit HL1606 LED Strip PWM - Arduino lib
Bandwidth Monitor
The data used to change the LED-strip is feed from the gateway using the bwbar utility for Linux. It outputs a text file every other second containing the current bandwidth utilization on the inbound and outbound interface. This text file is picked up by a shell script (sh), parsed, percentage of the maximum speed (9500kbit/s) is calculated and put in two variables. Last, the values are then passed over the network to an Arduino with an ethernet-shield using the wget utility.
A simple GET-http request containing the values as parameters, e.g. http://192.168.233.177/?up=6&dn=30, is sent to a basic webserver listening on the first Arduino. Once the values are received by the microcontroller, they're parsed to integers and transferred over a I2C/TWI-bus to the second LED-driving Arduino.
The second Arduino is the LED-driver and is responsible for updating and driving the strip. It had to be on a separate device because the ethernet-shield requires SPI, as does the LED strip, and there's only one hardware SPI-interface. It might be possible to put everything on one device and address ethernet/strip when needed, but I decided it was too time consuming to look into at the moment. The update rate of the LED strip could also suffer (as the 3 LED colors are controlled/dimmed by PWM).
To drive 128 LEDs without flickering due to low update frequency or spaz out due too overlapping frequency in the shift-register. There is a lot of details on the HL1606 in the Arduino-lib examples by Adafruit.
Download the shell script:
- Download monitor update script
Download the Arduino source code:
- Download Web Server Interface
- Download LED Driver - Requires the HL1606-LED-Strip-PWM Arduino library to be installed
Power
A 5V 2.5A powersupply is powering the LEDs and the Arduinos. The maximum driving current for one LED section is unknown, but the Adafruit product page states 120mA for 2 LEDs including the HL1606 (which seem a bit high to me).
I have yet to measure the actual current drown.
Mount
I wanted to make the monitor bars to be huge and as long as possible to get satisfactory resolution. To fit the space on the wall, I ended on the final dimension of 2 meters long and 15 cm height. That's 2x64 LEDs for download and upload monitor bar.
To mount the LED strips, I first made a 2 meter long base plate out of 10 pieces of 15x20 cm plexiglass plates glued together using regular CA-glue. Drilled holes for each 20 cm section, pulled fishing string through the holes, put double sided adhesive padding next to the holes, and tighned the string to get a firm fit. Remember, the LED strips will hang vertically and gravity will pull the strips down.
Using 4 hooks and double feed of fishing string, the entire plate with the two Arduino devices and LED strips is lifted into place. The assembly is hanging 8.5 cm away from the wall.
The only wires connected to the assembly is 5V power and an ethernet cable connected to a switch.