Video How To - Phoney TV
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LMs is Logitech Media Server. It's the same as Sonos (more like 'hand made') based on a Server (LMS) and clients (as Sonos Speakers).
I was looking for a solution to stream music across the house having also the ability to sync specific speakers to sound same time / same music.
Tried some solutions, started to think on Sonos (too expensive for me) so I started to investigate LMS.
The current version is distributed for free here: http://www.mysqueezebox.com/download. You can install this in a Raspberry Pi (I have my server in a RPI 1 and goes pretty fast).
Then the Clients (Speakers) I use PiCorePlayer (https://sites.google.com/site/picoreplayer/home/news) with a HiFi HAT attached to each client (https://www.hifiberry.com/).
There's a plugin for Vera and works super cool with OpenHab.
Let me know if you have questions. I'll be happy to share specifics.
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@Dave-Dan @petewill I use LMS as well, but mainly with the "official" hardware players. Still a large used market for those (search ebay for squeezebox). I have first gen Slim Devices players all the way to the latest ones released by Logitech. There's a great plugin for HomeSeer as well. We use them for automated alarm clocks (Squeezebox Radio's mainly), voice announcements, status displays and music of course :D.
Cheers
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@petewill Have you, or anyone else for that matter, looked at upgrading this code to compile under MySensors ver 2.0? I've setup multiple versions of the library so I can get it compiled under 1.4, but would like to move all my sensors to 2.0, if possible. If not, I'll look at changing the code after I finish with the hardware build.
Thanks for your work on this, and thanks to @BulldogLowell for the great project, been wanting to do a faketv type setup for some time now.
P.S.) your fritzing layout is missing the ground connection on the Pro Mini.
Chief P
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@petewill Have you, or anyone else for that matter, looked at upgrading this code to compile under MySensors ver 2.0? I've setup multiple versions of the library so I can get it compiled under 1.4, but would like to move all my sensors to 2.0, if possible. If not, I'll look at changing the code after I finish with the hardware build.
Thanks for your work on this, and thanks to @BulldogLowell for the great project, been wanting to do a faketv type setup for some time now.
P.S.) your fritzing layout is missing the ground connection on the Pro Mini.
Chief P
@chief I haven't upgraded to 2.0 yet. It's on the list but it will take me quite a while (I have a lot of sensors) so I need a good chunk of time to do it. I'll update the code then but if you get to it first please do share it :)
And, thanks for pointing out the missing ground! Good catch. I'll fix that now. -
@jimbolaya Something like this should work: http://www.digikey.com/products/en?keywords=IPP055N03LGXKSA1-ND.
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Thx for the reply @Sparkman. The link you included brings me to a page that lists all their products. Could you please check and repost?
@jimbolaya Sorry, link is now fixed.
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I had to update my firmware for MySensors version 2.0.0, I thought I would post it in case anyone comes across this post...
/* * PhoneyTV v3.2.0 * * This Sketch illuminates 6 sets of LED's in a random fashion as to mimic the * light eminating from a television. It is intended to make an empty home, * or an empty section of a home, appear to be occupied by someone watching * TV. As an alternative to a real television left on, this uses less than 1% * of the electrical energy. * * With the use of the MySensors plugin and gateway, PhoneyTV is intended to * be used with a controller (e.g. Vera or Raspberry PI). * * Sketch does not use any delays to create the random blinking as a way to * assure that communication back to the gateway is as unaffected as possible. * * You can adjust the length of the blink interval and its "twitchyness" by * modifying the random number generators, if you prefer more/less 'motion' in * in your unit. The lines are highlighted in the code, play around to create the * random effect you like. * * Sketch takes advantage of available PWM on pins 3, 5 & 6 using the white/blue LEDs * to allow fluctuations in the intensity of the light, enhancing the PhoneyTV's * realistic light effects. * * Created 12-APR-2014 * Free for distrubution * Credit should be given to MySensors.org for their base code for relay control * and for the radio configuration. Thanks Guys. * * 29-May-2014 * Version 2: Simplified the code, removing all redundant relay setup from original * code. Added an on/off momentary pushputton option to be set up on pin 2. Inproved * the dark dips for longer duration (can be configured) at intervals. * * 6-Jun-2015 * Version 3.1 * Updated for MySensors V1.4.1 * Contributed by Jim (BulldogLowell@gmail.com) Inspired by Josh >> Deltanu1142@gmail.com * * Version 3.2.0 updated for MySensors 2.0.0 by Jim (BulldogLowell@gmail.com) * How to video: https://youtu.be/p37qnl8Kjfc */ // Enable debug prints to serial monitor #define MY_DEBUG // Enable and select radio type attached #define MY_RADIO_NRF24 //#define MY_RADIO_RFM69 // Enable repeater functionality for this node //#define MY_REPEATER_FEATURE #include <SPI.h> #include <MySensors.h> #include <Bounce2.h> #define RADIO_RESET_DELAY_TIME 20 #define DEBUG_ON #ifdef DEBUG_ON #define DEBUG_PRINT(x) Serial.print(x) #define DEBUG_PRINTLN(x) Serial.println(x) #define SERIAL_START(x) Serial.begin(x) #else #define DEBUG_PRINT(x) #define DEBUG_PRINTLN(x) #define SERIAL_START(x) #endif const byte buttonPin = 2; const byte ledPin3 = 3; // White using PWM const byte ledPin4 = 4; // Red const byte ledPin5 = 5; // Blue using PWM const byte ledPin6 = 6; // Blue using PWM const byte ledPin7 = 7; // Green const byte ledPin8 = 8; // White (No PWM) Bounce debouncer = Bounce(); byte oldValue = 0; boolean state = false; boolean oldState = false; int dipInterval = 10; unsigned int darkTime = 250; unsigned long currentDipTime; unsigned long dipStartTime; unsigned long currentMillis; byte ledState = LOW; unsigned long previousMillis = 0UL; byte led = 5; unsigned long interval = 2000UL; unsigned int twitch = 50; int dipCount = 0; int analogLevel = 100; boolean timeToDip = false; boolean gotAck=false; MyMessage msg(1,V_LIGHT); void before() { state = loadState(1)? 1 : 0; } void setup() { SERIAL_START(115200); pinMode(ledPin3, OUTPUT); pinMode(ledPin4, OUTPUT); pinMode(ledPin5, OUTPUT); pinMode(ledPin6, OUTPUT); pinMode(ledPin7, OUTPUT); pinMode(ledPin8, OUTPUT); pinMode(buttonPin, INPUT_PULLUP); // debouncer.attach(buttonPin); debouncer.interval(50); // DEBUG_PRINTLN(F("Sensor Presentation Complete")); } void presentation() { // Send the sketch version information to the gateway and Controller sendSketchInfo("PhoneyTV", "1.5"); present(1, S_LIGHT); } void loop() { debouncer.update(); byte value = debouncer.read(); if (value != oldValue && value == 0) { state = !state; send(msg.set(state ? 1 : 0)); // while(!gotAck) // { // gw.send(msg.set(state), true); // gw.wait(RADIO_RESET_DELAY_TIME); // } // gotAck = false; DEBUG_PRINT(F("State Changed to:")); DEBUG_PRINTLN(state? F("PhoneyTV ON") : F("PhoneyTV OFF")); } oldValue = value; if (state) { if (timeToDip == false) { currentMillis = millis(); if (currentMillis - previousMillis > interval) { previousMillis = currentMillis; interval = random(750, 4001); //Adjusts the interval for more/less frequent random light changes twitch = random(40, 100); // Twitch provides motion effect but can be a bit much if too high dipCount++; } if (currentMillis - previousMillis < twitch) { led = random(3, 9); analogLevel = random(50, 255); // set the range of the 3 pwm leds ledState = !ledState; switch (led) //for the three PWM pins { case 3: pwmWrite(); break; case 5: pwmWrite(); break; case 6: pwmWrite(); break; default: digitalWrite(led, ledState); } if (dipCount > dipInterval) { timeToDip = true; dipCount = 0; dipStartTime = millis(); darkTime = random(50, 150); dipInterval = random(5, 250); // cycles of flicker } } } else { DEBUG_PRINTLN(F("Dip Time")); currentDipTime = millis(); if (currentDipTime - dipStartTime < darkTime) { for (int i = 3; i < 9; i++) { digitalWrite(i, LOW); } } else { timeToDip = false; } } } else { if (state != oldState) { for (int i = 3; i < 9; i++) { digitalWrite(i, LOW); } } } oldState = state; } void receive(const MyMessage &message) { // We only expect one type of message from controller. But we better check anyway. if (message.type==V_LIGHT) { // Change relay state state = message.getBool()? 1 : 0; // Store state in eeprom saveState(message.sensor, message.getBool()); // Write some debug info Serial.print("Incoming change for sensor:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println(message.getBool()); } } void pwmWrite() { if (ledState == HIGH) { analogWrite(led, analogLevel); } else { digitalWrite(led, LOW); } }
