The MSGEQ7 library provides an interface to an arbitrary number of MSGEQ7 chips, to convert analog voltage output from the chips to digital data. The data is of values from 0 to 255 (8 bits). Output from each chip, which is input to the library, is referred to in the documentation for this library as a "channel".
The MSGEQ7 is an IC designed to analyze sound (actually, any signal of varying voltages; in the case of sound or music, a signal as from a microphone). The chip measures aspects of input in seven frequency bands, and can provide output related to one (at a time) of these bands as an analog DC voltage signal. The frequency bands the chip analyzes are centered on: 63, 160, 400, 1K, 2.5K, 6.25K, and 16K Hertz.
This repository also includes source information for a Breakout Board with two MSGEQ7 chips. In a case of using two channels of output from a breakout board, referring to one channel as "mono" and two channels as "stereo" makes sense.
- IDE 1.6.x with every Arduino compatibly
- Sparkfun Spectrum Shield compatible
- Reads 1-n MSGEQ7 sensors
- Compact and fast implementation
- More compact and flexible 8 bit resolution
- Optional 10 bit resolution
- Value smoothing
- Tools to reduce noise
- A Breakout Board.
- Led: blinks led, shows basic usage
- Serial: shows spectrum via serial and how to use more channels
- FastLED: blinks led strip with different frequencies. Shows how to use different syntax. Uses FastLED library
To use the MSGEQ7 you first need a few other parts and connect them properly. Make sure the 33pF capacitor and the 200k Ohm resistor are precise. Otherwise the frequencies may be off. See the data sheet for more information.
Additionally this repository also contains a full instruction of how to build your own MSGEQ7 Breakout Board.
- 2x MSGEQ7 IC
- 1x Audio Jack 3.5mm (or any other audio input)
- 2x 10nF Capacitor
- 4x 100nF Capacitor
- 2x 33pF Capacitor
- 2x 200k Ohm Resistor
- Led or Led strips
- 1x 220 Ohm Resistor (for Led)
This would be an example breadboard setup for the Led example.
The MSGEQ7 Breakout Board lets you easily hook up an audio source or microphone to your microcontroller. You may also use a 2nd audio output to pass the audio signal to music boxes again. You can solder a 6 or 8 pin header to the board and connect it to a breadboard for example. It is fully open source so you can create a copy for yourself or modify it.
- Stereo music analyze
- Audio input via 3.5mm Jack
- Additional audio output
- Additional audio in/output via pin header
- Mounting holes
- Breadboard compatible
- Easy to solder (DIP parts)
- Open Source Hardware
- 1x Breakout Board
- 2x MSGEQ7 IC
- 2x Audio Jack 3.5mm
- 8 Pin Header Male
- 2x IC Socket 8 Pins (optional)
- 2x 10nF Capacitor
- 4x 100nF Capacitor
- 2x 33pF Capacitor
- 2x 200k Ohm Resistor
You can find all needed files in the board folder. Click view raw to download the PDF files.
You need to cut off the area around the audio jack a bit first to fit them better. A knife will work best here. After this just solder all components, starting with the capacitors and resistors to the IC sockets, the audio jacks and pin header. Any beginner can do this, no SMD component is used.
Install the library as you are used to. More information can be found here.
For a very fast library example see the MSGEQ7_LED example.
Every CMSGEQ7
instance needs pins passed via template to optimize the code.
The reset and strobe pin can be any digital pin on the board. Those are connected to each MSGEQ7 IC in parallel. You can input as many analog pins as you have MSGEQ7 ICs. For example only use a single IC for mono mode, 2 for stereo or more for surround.
If you want to smooth the readings with the last reading pass 0-255 as first argument. 0 Will disable smoothing, 255 will take 100% of the previous value. 191-223 is suggested if smoothing is desired.
Function Prototype:
template <uint8_t smooth, uint8_t resetPin, uint8_t strobePin
uint8_t firstAnalogPin, uint8_t ...analogPins>
class CMSGEQ7;
Examples:
// Single MSGEQ7 IC, Smoothing enabled (75%)
CMSGEQ7<191, 6, 4, A0> MSGEQ7;
// Two MSGEQ7 ICs (stereo), Smoothing disabled (0%)
CMSGEQ7<0, 6, 4, A0, A1> MSGEQ7;
Do whatever is required to initialize the ICs and resets it.
Function Prototype:
void begin(void);
Example:
void setup() {
// This will set the ICs ready for reading
MSGEQ7.begin();
}
Basic read function. Reads all channels and saves value inside the buffer. You
can access the buffer with the get()
function. Up to 400FPS (on 16MHz) are
possible with 2 channels from what I've measured.
To automatically read every X seconds you may also use the 2nd function. Used
together with the ReadsPerSecond(f)
makro you can simply pass an FPS interval
to the reading function. The return value tells you if a new reading was made.
Function Prototypes:
bool read(void);
bool read(const uint32_t interval);
Examples:
#define MSGEQ7_INTERVAL ReadsPerSecond(50)
void loop() {
// Analyze MSGEQ7 ICs now. Will always return true.
bool newReading = MSGEQ7.read();
// Analyze without delay every interval
bool newReading = MSGEQ7.read(MSGEQ7_INTERVAL);
}
Resets ICs, so they start reading at 0 again. Normally this is not required
since it is done in the read()
function.
Function Prototype:
void reset(void);
Example:
void loop() {
// Reset the IC frequently, otherwise it will get out of sync after a while
MSGEQ7.reset();
}
Returns the data of the selected frequency and channel. By default this returns
an uint8_t
value, for 10bit resolution uint16_t
. Frequency values should be
0-6 where 0 is the lowest frequency (Bass) and 6 the highest.
Depending on how many analog pins you have attached you can select the channel here (0-n). You can also leave out the channel variable to get an average value of all channels.
The output only ranges from 0-255 to save memory and use it easier. You won't lose much information anyways. If you still want to use 10bit mode see makros
The IC has a standard noise at about 10-19. You should keep that in mind. Have a look at the Map Noise function to get rid of this.
Function Prototypes:
MSGEQ7_data_t get(const uint8_t frequency, const uint8_t channel);
MSGEQ7_data_t get(const uint8_t frequency);
Examples:
void loop() {
// Read bass frequency (of all channels)
uint8_t input = MSGEQ7.get(MSGEQ7_BASS);
// Read mid frequency (of channel 0)
uint8_t input = MSGEQ7.get(MSGEQ7_MID, 0);
}
Returns the overall volume of all frequencies of a channel. By default this
returns an uint8_t
value, for 10bit resolution uint16_t
. The volume however
is not that useful actually.
Depending on how many analog pins you have attached you can select the channel here (0-n). You can also leave out the channel variable to get an average volume of all channels.
Function Prototypes:
MSGEQ7_data_t getVolume(uint8_t channel);
MSGEQ7_data_t getVolume(void);
Examples:
void loop() {
// Read volume (of all channels)
uint8_t input = MSGEQ7.getVolume();
// Read volume (of channel 0)
uint8_t input = MSGEQ7.getVolume(0);
}
Sets pins to input again to safely remove connections. This is normally not required.
Function Prototype:
void begin(void);
Example:
void setup() {
// This will set the ICs pin to input again
MSGEQ7.end();
}
Normally when using MSGEQ7 you get a background noise of around 15-19 (8bit
mode) even if no music is played. To get rid of this you can use the
mapNoise()
function to get rid of this. This macro can be used to remap the
input.
You can leave out the last 4 arguments, they will be replaced with default
values. See makros for more information. For 10 bit resolution the
function uses uint16_t
and 1023 as default maximum value.
Function Prototype:
inline MSGEQ7_data_t mapNoise(MSGEQ7_data_t x,
MSGEQ7_data_t in_min = MSGEQ7_IN_MIN,
MSGEQ7_data_t in_max = MSGEQ7_IN_MAX,
MSGEQ7_data_t out_min = MSGEQ7_OUT_MIN,
MSGEQ7_data_t out_max = MSGEQ7_OUT_MAX);
Example:
void loop() {
// Remove noise from input
input = mapNoise(input);
}
Inside MSGEQ7.h
some predefined makros are used to make code writing simpler.
You can optionally also enable 10 bit reading mode (0-1024) if you like to.
For most up to date definitions see MSGEQ7.h
source file.
// Software version
#define MSGEQ7_VERSION 121
// Use (optional) full 10 bit analog readings for MSGEQ7
//#define MSGEQ7_10BIT
// FPS makro
#define ReadsPerSecond(f) (1000000UL / (f))
// Basic frequencies definitions (0-6 valid, 7 channels)
#define MSGEQ7_0 0
#define MSGEQ7_1 1
#define MSGEQ7_2 2
#define MSGEQ7_3 3
#define MSGEQ7_4 4
#define MSGEQ7_5 5
#define MSGEQ7_6 6
#define MSGEQ7_BASS 0
#define MSGEQ7_LOW 0
#define MSGEQ7_MID 3
#define MSGEQ7_HIGH 5
// Resolution dependant settings
#ifdef MSGEQ7_10BIT
typedef uint16_t MSGEQ7_data_t;
#define MSGEQ7_IN_MIN 20
#define MSGEQ7_IN_MAX 1023
#define MSGEQ7_OUT_MIN 0
#define MSGEQ7_OUT_MAX 1023
#else
typedef uint8_t MSGEQ7_data_t;
#define MSGEQ7_IN_MIN 20
#define MSGEQ7_IN_MAX 255
#define MSGEQ7_OUT_MIN 0
#define MSGEQ7_OUT_MAX 255
#endif
Contact information can be found here:
1.2.2 Release (16.04.2016)
* Fixed mapNoise() example and keyword #4
1.2.1 Release (05.03.2016)
* Added 1.6.x library schema
* Added board pictures
* Fix reading the wrong frequency over time
* Smooth from 0-255 now
* Fix compiler warnings
* Renamed map function, moved outside the main class
* Improved documentation
1.2 Release (23.04.2015)
* Added breakout board files v1.0
* Optimized performance
* Variable number of ICs readable
* Added optional 10bit resolution
* Added more functions/tools
* Improved examples
* Added MSGEQ7_VERSION definition
* Added library.properties
1.1 Release (10.07.2014)
* Changed syntax
* Optimized performance
* Added more examples
1.0 Release (13.04.2014)
* Added general functionality
If you use this library for any cool project let me know!
Copyright (c) 2014-2016 NicoHood
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