基于Arduino的音乐动感节奏灯

时间:2024-01-22 13:03:24

1、音乐动感节奏灯是个什么东西?

  前段时间听音乐觉得无聊,便想着音乐光听也没意思啊,能不能 “看见” 音乐呢?于是谷歌了一番,发现还真有人做了将音乐可视化的东西,那就是音乐节奏灯。说的简单点就是LED灯光颜色亮度等随着音乐的节奏而发生变化,看了下他们的实现方法有很多,不过大都比较复杂,而且灯只能够做节奏灯也比较浪费,于是我便动手做了一个既可以当作普通台灯使用,又可以随着音乐而闪烁的动感节奏灯,一举两得。

2、做这个东西需要准备哪些材料?

  工欲善其事,必先利其器。那么做这样一个音乐动感节奏等需要准备哪些材料呢?

  •   Arduino UNO 开发板
  •        声音传感器(最好买Arduino专用的)
  •        BLE蓝牙4.0模块
  •        WS2812B彩色灯带
  •        灯罩
  •        3D打印底座
  •        电源线和杜邦线若干

以上材料可以在淘宝买到,灯罩和3D打印的底座可以按照自己的实际需求来进行自己选择,为了防止打广告的嫌疑我就不放购买链接了,可以自行设计打印~

3、做这个东西需该怎么做?

  准备好上述的材料之后,我们就可以开始进行灯的制作啦~,节奏灯的主要结构如下图:

我们使用Arduino UNO作为主要的计算和处理模块,蓝牙4.0模块和手机进行通信,利用手机APP来选择模式(后续会讲),在节奏灯的模式下,通过声音传感器来采集声音,通过得到的声音来控制灯带的颜色和闪烁,在彩色灯的模式下,利用手机来控制灯的颜色,理论上的有160万可调颜色。接下来介绍下详细的步骤。

3.1 安装开发环境

  Arduino UNO 开发的环境为Arduino IDE,软件下载地址为 https://www.arduino.cn/thread-5838-1-1.html ,默认安装为最新版即可。安装完IDE之后还需要安装第三方的库。

  1) WS2812B的库 FastLED, 选择 项目->加载库->管理库,然后在输入栏输入FastLED,选择最新的版本安装,FastLED库的更多使用方法可以参考 http://www.taichi-maker.com/homepage/reference-index/arduino-library-index/fastled-library/

                                     

  2)  物联网开发平台库 Blinker, 在Blinker 官网https://doc.blinker.app 页面下载最新的Blinker库,然后:

    Window将下载好的blinker库解压到 我的电脑>文档>Arduino>libraries 文件夹中
    Mac OS将下载好的blinker库解压到 文稿>Arduino>libraries 文件夹中

    可以在文件->示例 查看库是否安装成功。

3.2 连接线路

  具体的线路图由于时间原因没有画,所以直接按照后续的代码可以找到每个模块的连接方式,当然这些连接方式都可以自定义,然后在代码内做简单修改即可。需要注意的是蓝牙模块采用软串口连接,即RX,TX连接在ARDUINO UNO的2 和 3 号脚,而不是0和1 号脚,这个在BLINKER的网站上会说明,如果你代码烧录不了,查查是不是这个原因。

3.3 代码编写

  1 #define BLINKER_PRINT Serial
  2 #define BLINKER_BLE
  3 
  4 #include <FastLED.h>
  5 #include <Blinker.h>
  6 
  7 /** BASIC CONFIGURATION  **/
  8 
  9 //The amount of LEDs in the setup
 10 #define NUM_LEDS 100
 11 //The pin that controls the LEDs
 12 #define LED_PIN 6
 13 //The pin that we read sensor values form
 14 #define ANALOG_READ 0
 15 
 16 //Confirmed microphone low value, and max value
 17 #define MIC_LOW 0.0
 18 #define MIC_HIGH 300.0
 19 /** Other macros */
 20 //How many previous sensor values effects the operating average?
 21 #define AVGLEN 5
 22 //How many previous sensor values decides if we are on a peak/HIGH (e.g. in a song)
 23 #define LONG_SECTOR 20
 24 
 25 //Mneumonics
 26 #define HIGH 3
 27 #define NORMAL 2
 28 
 29 //How long do we keep the "current average" sound, before restarting the measuring
 30 #define CYCLES 30 * 1000
 31 
 32 
 33 float fscale( float originalMin, float originalMax, float newBegin, float newEnd, float inputValue, float curve);
 34 void insert(int val, int *avgs, int len);
 35 int compute_average(int *avgs, int len);
 36 void visualize_music();
 37 
 38 //How many LEDs to we display
 39 int curshow = NUM_LEDS;
 40 
 41 /*Not really used yet. Thought to be able to switch between sound reactive
 42 mode, and general gradient pulsing/static color*/
 43 int mode = 0;
 44 
 45 //Showing different colors based on the mode.
 46 int songmode = NORMAL;
 47 
 48 //Average sound measurement the last CYCLES
 49 unsigned long song_avg;
 50 
 51 //The amount of iterations since the song_avg was reset
 52 int iter = 0;
 53 
 54 //The speed the LEDs fade to black if not relit
 55 float fade_scale = 1.2;
 56 
 57 //Led array
 58 CRGB leds[NUM_LEDS];
 59 
 60 /*Short sound avg used to "normalize" the input values.
 61 We use the short average instead of using the sensor input directly */
 62 int avgs[AVGLEN] = {-1};
 63 
 64 //Longer sound avg
 65 int long_avg[LONG_SECTOR] = {-1};
 66 
 67 
 68 // LED Model 1/Music LED 2/Color LED
 69 int LED_Model = 2;
 70 
 71 //Keeping track how often, and how long times we hit a certain mode
 72 struct time_keeping {
 73   unsigned long times_start;
 74   short times;
 75 };
 76 
 77 //How much to increment or decrement each color every cycle
 78 struct color {
 79   int r;
 80   int g;
 81   int b;
 82 };
 83 
 84 struct time_keeping high;
 85 struct color Color; 
 86 // when you use the MusicLED as a Color LED
 87 CRGB LEDColor(0,0,0);    
 88 uint8_t Bright = 255;
 89 
 90 // declare the button
 91 BlinkerRGB RGB1("RGBKey");
 92 BlinkerButton Button1("switch");
 93 
 94 
 95 // rgb1_callback
 96 void rgb1_callback(uint8_t r_value, uint8_t g_value, uint8_t b_value, uint8_t bright_value)
 97 {
 98   // change the color of strip by your set on Blinker
 99       LEDColor.r = r_value;
100       LEDColor.g = g_value;
101       LEDColor.b = b_value;
102       Bright = bright_value;
103       fill_solid(leds,NUM_LEDS,LEDColor);
104   
105   FastLED.show();
106 }
107 
108 void button1_callback(const String & state) {
109   if(LED_Model == 1)
110   {
111     LEDColor.r = 255;
112     LEDColor.g = 255;
113     LEDColor.b = 255;
114     Bright = 0;
115     fill_solid(leds,NUM_LEDS,LEDColor);
116     BLINKER_LOG2("strip_state: ","OFF");
117     LED_Model = 2;
118   }
119   else if(LED_Model == 2)
120   {
121     LED_Model = 1;
122   }
123   FastLED.show();
124 }
125 
126 
127 void setup() {
128   Serial.begin(9600);
129   //Set all lights to make sure all are working as expected
130   FastLED.addLeds<NEOPIXEL, LED_PIN>(leds, NUM_LEDS);
131   for (int i = 0; i < NUM_LEDS; i++) 
132     leds[i] = CRGB(0, 0, 255);
133   FastLED.show(); 
134   delay(1000);  
135 
136   //bootstrap average with some low values
137   for (int i = 0; i < AVGLEN; i++) {  
138     insert(250, avgs, AVGLEN);
139   }
140 
141   //Initial values
142   high.times = 0;
143   high.times_start = millis();
144   Color.r = 0;  
145   Color.g = 0;
146   Color.b = 1;
147 
148     Blinker.begin();
149     //attach the RGB1 SlidersRGB
150     RGB1.attach(rgb1_callback);
151     Button1.attach(button1_callback);
152 }
153 
154 /*With this we can change the mode if we want to implement a general 
155 lamp feature, with for instance general pulsing. Maybe if the
156 sound is low for a while? */
157 void loop() {
158   Blinker.run();
159   
160   if(LED_Model == 1)
161     visualize_music();
162    
163   delay(1);       // delay in between reads for stability
164 }
165 
166 
167 /**Funtion to check if the lamp should either enter a HIGH mode,
168 or revert to NORMAL if already in HIGH. If the sensors report values
169 that are higher than 1.1 times the average values, and this has happened
170 more than 30 times the last few milliseconds, it will enter HIGH mode. 
171 TODO: Not very well written, remove hardcoded values, and make it more
172 reusable and configurable.  */
173 void check_high(int avg) {
174   if (avg > (song_avg/iter * 1.1))  {
175     if (high.times != 0) {
176       if (millis() - high.times_start > 200.0) {
177         high.times = 0;
178         songmode = NORMAL;
179       } else {
180         high.times_start = millis();  
181         high.times++; 
182       }
183     } else {
184       high.times++;
185       high.times_start = millis();
186 
187     }
188   }
189   if (high.times > 30 && millis() - high.times_start < 50.0)
190     songmode = HIGH;
191   else if (millis() - high.times_start > 200) {
192     high.times = 0;
193     songmode = NORMAL;
194   }
195 }
196 
197 //Main function for visualizing the sounds in the lamp
198 void visualize_music() {
199   int sensor_value, mapped, avg, longavg;
200   
201   //Actual sensor value
202   sensor_value = analogRead(ANALOG_READ);
203   Serial.println(sensor_value);
204   
205   //If 0, discard immediately. Probably not right and save CPU.
206   if (sensor_value == 0)
207     return;
208 
209   //Discard readings that deviates too much from the past avg.
210   mapped = (float)fscale(MIC_LOW, MIC_HIGH, MIC_LOW, (float)MIC_HIGH, (float)sensor_value, 2.0);
211   avg = compute_average(avgs, AVGLEN);
212 
213   if (((avg - mapped) > avg*0.8)) //|| ((avg - mapped) < -avg*0.8))
214     return;
215   
216   //Insert new avg. values
217   insert(mapped, avgs, AVGLEN); 
218   insert(avg, long_avg, LONG_SECTOR); 
219 
220   //Compute the "song average" sensor value
221   song_avg += avg;
222   iter++;
223   if (iter > CYCLES) {  
224     song_avg = song_avg / iter;
225     iter = 1;
226   }
227     
228   longavg = compute_average(long_avg, LONG_SECTOR);
229 
230   //Check if we enter HIGH mode 
231   check_high(longavg);  
232 
233   if (songmode == HIGH) {
234     fade_scale = 3;
235     Color.r = 5;
236     Color.g = 3;
237     Color.b = -1;
238   }
239   else if (songmode == NORMAL) {
240     fade_scale = 2;
241     Color.r = -1;
242     Color.b = 2;
243     Color.g = 1;
244   }
245 
246   //Decides how many of the LEDs will be lit
247   curshow = fscale(MIC_LOW, MIC_HIGH, 0.0, (float)NUM_LEDS, (float)avg, -1);
248 
249   /*Set the different leds. Control for too high and too low values.
250           Fun thing to try: Dont account for overflow in one direction, 
251     some interesting light effects appear! */
252   for (int i = 0; i < NUM_LEDS; i++) 
253     //The leds we want to show
254     if (i < curshow) {
255       if (leds[i].r + Color.r > 255)
256         leds[i].r = 255;
257       else if (leds[i].r + Color.r < 0)
258         leds[i].r = 0;
259       else
260         leds[i].r = leds[i].r + Color.r;
261           
262       if (leds[i].g + Color.g > 255)
263         leds[i].g = 255;
264       else if (leds[i].g + Color.g < 0)
265         leds[i].g = 0;
266       else 
267         leds[i].g = leds[i].g + Color.g;
268 
269       if (leds[i].b + Color.b > 255)
270         leds[i].b = 255;
271       else if (leds[i].b + Color.b < 0)
272         leds[i].b = 0;
273       else 
274         leds[i].b = leds[i].b + Color.b;  
275       
276     //All the other LEDs begin their fading journey to eventual total darkness
277     } else {
278       leds[i] = CRGB(leds[i].r/fade_scale, leds[i].g/fade_scale, leds[i].b/fade_scale);
279     }
280   FastLED.show(); 
281 }
282 //Compute average of a int array, given the starting pointer and the length
283 int compute_average(int *avgs, int len) {
284   int sum = 0;
285   for (int i = 0; i < len; i++)
286     sum += avgs[i];
287 
288   return (int)(sum / len);
289 
290 }
291 
292 //Insert a value into an array, and shift it down removing
293 //the first value if array already full 
294 void insert(int val, int *avgs, int len) {
295   for (int i = 0; i < len; i++) {
296     if (avgs[i] == -1) {
297       avgs[i] = val;
298       return;
299     }  
300   }
301 
302   for (int i = 1; i < len; i++) {
303     avgs[i - 1] = avgs[i];
304   }
305   avgs[len - 1] = val;
306 }
307 
308 //Function imported from the arduino website.
309 //Basically map, but with a curve on the scale (can be non-uniform).
310 float fscale( float originalMin, float originalMax, float newBegin, float
311     newEnd, float inputValue, float curve){
312 
313   float OriginalRange = 0;
314   float NewRange = 0;
315   float zeroRefCurVal = 0;
316   float normalizedCurVal = 0;
317   float rangedValue = 0;
318   boolean invFlag = 0;
319 
320 
321   // condition curve parameter
322   // limit range
323 
324   if (curve > 10) curve = 10;
325   if (curve < -10) curve = -10;
326 
327   curve = (curve * -.1) ; // - invert and scale - this seems more intuitive - postive numbers give more weight to high end on output 
328   curve = pow(10, curve); // convert linear scale into lograthimic exponent for other pow function
329 
330   // Check for out of range inputValues
331   if (inputValue < originalMin) {
332     inputValue = originalMin;
333   }
334   if (inputValue > originalMax) {
335     inputValue = originalMax;
336   }
337 
338   // Zero Refference the values
339   OriginalRange = originalMax - originalMin;
340 
341   if (newEnd > newBegin){ 
342     NewRange = newEnd - newBegin;
343   }
344   else
345   {
346     NewRange = newBegin - newEnd; 
347     invFlag = 1;
348   }
349 
350   zeroRefCurVal = inputValue - originalMin;
351   normalizedCurVal  =  zeroRefCurVal / OriginalRange;   // normalize to 0 - 1 float
352 
353   // Check for originalMin > originalMax  - the math for all other cases i.e. negative numbers seems to work out fine 
354   if (originalMin > originalMax ) {
355     return 0;
356   }
357 
358   if (invFlag == 0){
359     rangedValue =  (pow(normalizedCurVal, curve) * NewRange) + newBegin;
360 
361   }
362   else     // invert the ranges
363   {   
364     rangedValue =  newBegin - (pow(normalizedCurVal, curve) * NewRange); 
365   }
366 
367   return rangedValue;
368 }

上述代码编译无误后上传到Arduino UNO即可。

3.4 下载并使用Blinker软件连接

  Blinker软件的安装包可以在官网上找到:

安装好之后注册账号,登陆,在主页面右上角选择-->添加设备-->Arduino-->蓝牙接入,然后会自动发现我们的蓝牙,连接上之后,如图。

                                                                                          

上面表示是否已经连接,现在表示已连接。然后添加上面的两个组件,编辑组件参数如下:

 

 

 

完成之后便可以通过RGB滑条来控制颜色,通过模式按钮来控制灯的模式。

3.5 灯的组装

   我是自己在网上买的灯罩,然后根据自己的需求3D打印的底座,大家可以发挥自己的想象力来创作出不一样的外观~

 然后来一波安装完成的照片:

最后更新一波实测视频(由于不能同时录像和控制,所以只放了节奏灯效果):

地址:https://www.bilibili.com/video/av38471827/