2 X 100W Class D Bluetooth Audio Amplifier Board – TSA7510B(TWS/Apt-X)

TSA7510B is a 2x100W audio amplifier board with a new AudioB plus Bluetooth module that supports Apt-X. It has perfect class-D architecture(Based on TPA3221) and each channel has 100W power output. Both of channels are capable of outputting nominal power simultaneously and continuously. This board can be powered by any DC12V-30V power supply. It can be used to drive any 2Ω,4Ω or 8Ω passive speakers. TSA7510 can also be connected with our TSA1000,TSA1010 or TSA1020 external audio volume control board. People can adjust the audio volume by rotating the real knob.

The highlight point is Apt-X and TWS supported. Therefore, Users can stream audio to 2 pair amplifier boards at the same time wirelessly. It’s perfect for your Hi-Fi application. You may wish to pair with a mobile phone or a computer (etc). Power the amplifier board. Use your phone or PC (etc) to search for a new Bluetooth device. The module will appear as “TSA7510B”. You don’t need a PIN, pair it and then you can play music.

  • TSA7510 can auto detect the Aux in/Line in Audio input. Bluetooth Audio source has higher priority. When Bluetooth audio is paused or bluetooth is disconnected. The amplifier will output the Aux in/Line in audio. If you want to manually select the Aux in/Line in and bluetooth audio source, please choose TSA7498B or TSA7499B
  • There have an extra LINE OUT audio output jack. It can also be connected with a subwoofer amplifier board.
  • BVC Port: BVC port can be connected with our Audio volume controller to control the Bluetooth audio volume.

TSA7510B can auto detect the Aux in/Line in Audio input. Bluetooth Audio source has higher priority. When Bluetooth audio is paused or bluetooth is disconnected. The Amplifier will output the Aux in/Line in audio.

TSA7510B + TSA1000, Both Aux in and Bluetooth audio volume can be controlled via BVC port

2 boards work in TWS mode

*User must remove the slave board Aux in Enable jumper before pairing 2 boards

  • S1 – Long press 3s into pairing mode. Long press 6s clear the pairing info.
  • S1+S2 – Long press 1s into TWS slave mode.
  • S1+S3 – Long press 1s into TWS master mode.
  • S2+S3 – Long press 1s disconnect TWS connection.

Specification:

Specifications typical @ +25℃, Powered by 24V DC, unless otherwise noted. Specifications subject to change without notice.

Parameter Condition Min Typ Max

Supply Voltage (VDC)

10 24 26
Power output per channel RL= 3Ω, 10% THD+N 112W
RL= 4Ω, 10% THD+N 105W
RL= 3Ω, 1% THD+N 100W
RL= 4Ω, 1% THD+N 88W
THD+N 1W 0.02%
SNR A-weighted,Gain= 18 dB 108dB
DNR A-weighted,Gain= 18 dB 109dB
Minimum Load Impedance
Gain 18dB 24dB 34dB
Efficiency 100W @ 4Ohm 90%
Input Impedance 18dB 48KΩ
24dB 24KΩ
30dB 12KΩ
34dB 7.7KΩ

Features:

  • Dimensions: 122mm x 80mm x 18.6mm
  • aptX, aptX Low Latency, SBC and AAC
  • Bluetooth 4.2
  • Bluetooth audio volume control port(BVC)
  • Aux in/LIne in autodetect
  • Subwoofer output port
  • Working voltage: DC 12V-30V
  • Over/under voltage protection
  • Overcurrent protection
  • Over temperature protection

Applications:

  • Personal computer
  • Background music system
  • Musical instrument amplifiers
  • Home DIY
  • Car audio

This product can be purchased from here:

3513706545252-2-x-100w-class-d-bluetooth-audio-amplifier-board-tsa7510btws-apt-x

2 x 100W Class D Bluetooth Audio Amplifier Board - TSA7510B(TWS/Apt-X)

$67.76$69.11

2 x 100W Class D Bluetooth Audio Amplifier Board – TSA7499B(Apt-X)

TSA7499B is designed for audio amplifier manufacturing factories or DIY electronics makers/users.

Bluetooth/LINE IN select switch and audio input ports are designed with JST connectors. That allows users to install this amplifier board in a box and connect an external switch and RCA/3.5mm audio jack plug to make their own audio amplifier. (more…)

2 x 100W + 200W 3 Channels Audio Amplifier Board – TSA7600

This amplifier does not have Bluetooth.

This is TSA7600 2x100W + 220W audio amplifier board. It has perfect class-D architecture (based on TPA3221) and 2 channels have 100W power output and another one channel has 200W power output. All the channels are capable of outputting nominal power simultaneously and continuously. This board can be powered by any DC 12V-30V power supply. It can be used to drive any 4Ω or 8Ω passive speakers. (more…)

Amarino Shield Experiment 3- LM35 temperature sensor and LED controller

Fully assembled kit (4)

This is one of the most interesting experiments that uses Amarino shield and Amarino toolkit application. If you have never heard of Amarino toolkit and the shield, we recommend you to go the following pages:

  1. About Amarino toolkit
  2. About Amarino shield

This experiment with Amarino shield is similar to our previous tutorials on Sensor Graph- basic experiment and Sensor graph & LED controller together.

tutorials Sensor Graph basic experiment and Sensor graph and LED controller together. – See more at: http://www.buildcircuit.com/amarino-shield-3-0-experiments-android-and-arduino/#sthash.hwn3GMIB.dpuf

You can get a list of other experiments with this shield at the end of this post.

Amarino shield 3

CONNECTION: In this experiment, the sensor signal from LM35 temperature sensor is fed to analog pin A0.

Check out the schematic of Amarino Shield 3.0

Steps:

a. Download Amarino and install on your Android Phone.

b. Download Amarino Library for Arduino and move it to the Libraries folder. You can check here if the Amarino team has upgraded the library. It’s always good to use the updated version 🙂 .

c. Download Temperature sensor (with LED controller) application and install on your phone. If you know Android Programming you can download the Android source code also.

d. Download Arduino code for this experiment  and upload to your Arduino. Here, you have to keep few things in mind:

POINT 1: In Amarino 3.0 DIY shield, you have to use the IC1 switch (1 P DIP switch) to switch off CD4094 while doing Amarino related experiments. If it is switched on, the CD4094 chip might affect your experiment.

POINT 2: The Arduino Sketch has its default baud rate set to 9600 bits/s. Therefore, your Bluetooth adapter should also have the same baud rate. Generally, the default baud rate of BlueSMiRF and general Bluetooth adapters is 9600 bps. However, if you want to change baud rate of BlueSMiRF module, follow this link. We have tested this experiment at 57600 bps and 9600 bps and it works perfectly well. You cannot change the baud rate of general Bluetooth adapters 🙁 .

e. Stack the Amarino shield over your Arduino and your Bluetooth adapter over the correct female header on the shield. The shield supports 3 types of Bluetooth adapters. Please check here to know which adapters are supported.

Test if Amarino application connects to the Bluetooth adapter: After installing the adapter on the shield, switch on the Bluetooth function of your phone, open the Amarino application and connect each other using the pairing code 1234. You can see the MAC ID of the Bluetooth adapter on the Amarino application interface. On the image shown below, you can see that there are two Bluetooth adapters with two different names and IDs registered on the application. Pressing the “Connect” button connects the application to the chosen adapter. You can connect only one adapter at one time.

Amarino Interface

A low cost general Bluetooth adapter is enough for this shield. You can purchase one at buildcircuit.net.

If you have never done any experiment related to Bluetooth adapter, we recommend you to try this one… CLICK HERE.

f. Keep the Bluetooth function of your phone alive, pair it up with the Bluetooth adapter using the pairing code: 1234 and note down the MAC ID of your Bluetooth adapter and type it on the text box of your Temperature sensor (with LED controller) application.

g. Connect to the Bluetooth adapter with your application and use the Temperature sensor (with LED controller) application to operate the 5mm white LED with PWM signals and see the temperature data on the application interface.

Amarino shield 3

Check out the following video:


Related tutorials:


You can purchase this versatile Amarino shield at buildcircuit.net and Etsy. The store is owned and operated by the team which operates buildcircuit.com.

Amarino shield in use (2)Buy now button buy at etsy


Amarino Shield Experiment 2- Sensor Graph and LED controller

Fully assembled kit (4)

This is one of the most interesting experiments that uses Amarino shield and Amarino toolkit application. If you have never heard of Amarino toolkit and the shield, we recommend you to go the following pages:

  1. About Amarino toolkit
  2. About Amarino shield

This experiment with Amarino shield is similar to our previous tutorials on Sensor Graph- basic experiment and Sensor graph & LED controller together.

tutorials Sensor Graph basic experiment and Sensor graph and LED controller together. – See more at: http://www.buildcircuit.com/amarino-shield-3-0-experiments-android-and-arduino/#sthash.hwn3GMIB.dpuf

You can get a list of other experiments with this shield at the end of this post.

sensor graph with LED controller

CONNECTION:

In this experiment, the sensor signal from LDR is fed to A1. You can also see A1 clearly on PCB.

Check out the schematic of Amarino Shield 3.0

Steps:

a. Download Amarino and install on your Android Phone.

b. Download Amarino Library for Arduino and move it to the Libraries folder. You can check here if the Amarino team has upgraded the library. It’s always good to use the updated version 🙂 .

c. Download Sensor Graph (with LED controller) application and install on your phone. If you know Android Programming you can download the Android source code also. You can also get the original Amarino source code. The original source code has the Sensor Graph interface only (which means… there is no LED controller slider on the application).

d. Download Arduino code for Sensor Graph (with LED controller)  and upload to your Arduino. Here, you have to keep few things in mind:

POINT 1: In Amarino 3.0 DIY shield, you have to use the IC1 switch (1 P DIP switch) to switch off CD4094 while doing Amarino related experiments. If it is switched on, the CD4094 chip might affect your experiment.

POINT 2: The Arduino Sketch has its default baud rate set to 9600 bits/s. Therefore, your Bluetooth adapter should also have the same baud rate. Generally, the default baud rate of BlueSMiRF and general Bluetooth adapters is 9600 bps. However, if you want to change baud rate of BlueSMiRF module, follow this link. We have tested this experiment at 57600 bps and 9600 bps and it works perfectly well. You cannot change the baud rate of general Bluetooth adapters 🙁 .

e. Stack the Amarino shield over your Arduino and your Bluetooth adapter over the correct female header on the shield. The shield supports 3 types of Bluetooth adapters. Please check here to know which adapters are supported.

Test if Amarino application connects to the Bluetooth adapter: After installing the adapter on the shield, switch on the Bluetooth function of your phone, open the Amarino application and connect each other using the pairing code 1234. You can see the MAC ID of the Bluetooth adapter on the Amarino application interface. On the image shown below, you can see that there are two Bluetooth adapters with two different names and IDs registered on the application. Pressing the “Connect” button connects the application to the chosen adapter. You can connect only one adapter at one time.

Amarino Interface

A low cost general Bluetooth adapter is enough for this shield. You can purchase one at buildcircuit.net.

If you have never done any experiment related to Bluetooth adapter, we recommend you to try this one… CLICK HERE.

f. Keep the Bluetooth function of your phone alive, pair it up with the Bluetooth adapter using the pairing code: 1234 and note down the MAC ID of your Bluetooth adapter and type it on the text box of your Sensor Graph (with LED controller) application.

g. Connect to the Bluetooth adapter with your application and use the Sensor Graph (with LED controller) application to operate the 5mm white LED with PWM signals and see the graph on the application interface.

The LED and LDR have been kept together so that LED light falls properly on the LDR and you can see the light sensor response clearly on the graph. If your room is highly illuminated, you can put a piece of paper for better results. The paper will block ambient light falling on the LDR.

Check out the following video and see how the sensor graph experiment looks


Related tutorials:


You can purchase this versatile Amarino shield at buildcircuit.net and Etsy. The store is owned and operated by the team which operates buildcircuit.com.

Amarino shield in use (2)Buy now button buy at etsy


Amarino Shield Experiment 1- RGB multicolor lamp using Amarino shield

Fully assembled kit (4)

This is one of the most interesting experiments that uses Amarino shield and Amarino toolkit application. If you have never heard of Amarino toolkit and the shield, we recommend you to go the following pages:

  1. About Amarino toolkit
  2. About Amarino shield

This experiment with Amarino shield is similar to our previous tutorials on RGB multicolor lamp using Amarino and RGB multicolor lamp with custom Bluetooth ID on Amarino Interface.

You can get a list of other experiments with this shield at the end of this post.

Multicolor lamp experiment

RGB LED and its connection on the shield:

We have used common cathode RGB LED for the multicolor lamp (RGB lamp) experiment. The connections are as follows

For Red: Digital Pin 3 has been used.

For Green: Digital Pin 6 has been used.

For Blue: Digital Pin 5 has been used.

Check out the schematic of Amarino Shield 3.0

Steps:

a. Download Amarino and install on your Android Phone.

b. Download Amarino Library for Arduino and move it to the Libraries folder. You can check here if the Amarino team has upgraded the library. It’s always good to use the updated version 🙂 .

c. Download multicolor lamp application and install on your phone. If you know Android Programming you can download the Android source code also. You can also get the original Amarino source code.

The multicolor lamp application

The multicolor lamp application

d. Download Arduino code for Multicolor Lamp and upload to your Arduino. Here, you have to keep few things in mind:

POINT 1: In Amarino 3.0 DIY shield, you have to use the IC1 switch (1 P DIP switch) to switch off CD4094 while doing Amarino related experiments. If it is switched on, the CD4094 chip might affect your experiment. 

POINT 2: The Arduino Sketch has its default baud rate set to 9600 bits/s. Therefore, your Bluetooth adapter should also have the same baud rate. Generally, the default baud rate of BlueSMiRF and general Bluetooth adapters is 9600 bps. However, if you want to change baud rate of BlueSMiRF module, follow this link. We have tested this experiment at 57600 bps and 9600 bps and it works perfectly well. You cannot change the baud rate of general Bluetooth adapters 🙁 .

e. Stack the Amarino shield over your Arduino and your Bluetooth adapter over the correct female header on the shield. The shield supports 3 types of Bluetooth adapters. Please check here to find out which adapters are supported. 

Test if Amarino application connects to the Bluetooth adapter: After installing the adapter on the shield, switch on the Bluetooth function of your phone, open the Amarino application and connect each other using the pairing code 1234. You can see the MAC ID of the Bluetooth adapter on the Amarino application interface. On the image shown below, you can see that there are two Bluetooth adapters with two different names and IDs registered on the application. Pressing the “Connect” button connects the application to the chosen adapter. You can connect only one adapter at one time.

Amarino Interface

A low cost general Bluetooth adapter is enough for this shield. You can purchase one at buildcircuit.net.

If you have never done any experiment related to Bluetooth adapter, we recommend you to try this one… CLICK HERE.

f. Keep the Bluetooth function of your phone alive, pair it up with the Bluetooth adapter using the pairing code: 1234 and note down the MAC ID of your Bluetooth adapter and type it on the text box of your RGB Lamp application.

g. Connect to the Bluetooth adapter with your application and operate the RGB LED using the installed Multicolor RGB Lamp application.

Check out the following video and see how the multicolor lamp experiment looks

Related tutorials:


You can purchase this versatile Amarino shield at buildcircuit.net and Etsy. The store is owned and operated by the team which operates buildcircuit.com.

Amarino shield in use (2)Buy now button buy at etsy


Amarino shield- CD4094 control with Arduino and Android Serial Emulator

Fully assembled kit (4)

This is the second experiment for Amarino shield. If you do not know anything about Amarino toolkit or this shield please click on the following links:

  1. About Amarino toolkit
  2. About Amarino shield

You can get a list of other experiments at the end of this post. Before you try this experiment, we recommend you to try experiment no. 1. In the experiment no.1, you will see how you can control the CD4094 and its corresponding LEDs without using Android phone.

In this experiment, you will see how we can convert a decimal number to its binary form using an Android serial emulator and Amarino shield. On the Amarino shield, you can see that there are 8 pcs of 3mm LEDs which represent the 8 bits. In your experiment, for example,  when you press 255?, you will see that all the LEDs are switched on representing 11111111 that results in actual decimal to binary conversion. Likewise, when you press 1?, you will see LEDs switched on in this pattern: 00000001, i.e. one LED is switched on and other are switched off.

For this experiment, you can use ANY KIND of Android emulator. Here are some examples of Android Serial Emulators. We have used BLUE TERM for this experiment. You can also search this application on your Android phone, it is available on Google Play Store.  Download source code of BLUE TERM(for programmers)

Experiment steps:

Step 1: Download the BLUETERM application or any other general Bluetooth serial emulator for your Android smart phone.

Step 2: DOWNLOAD ARDUINO SOURCE CODE and upload on to your Arduino.

Step 3: Stack the Amarino shield over your Arduino and connect a Bluetooth Adapter.

Please note that the Amarino shield supports 3 different types of Bluetooth Adapters, you can use any one of them. Check out the adapters supported by the shield.

For this experiment, we are using General Bluetooth adapter, the cheapest and the best one. 

The cheapest Bluetooth adapter is available at www.buildcircuit.net. BUY NOW.
Step 4: Connect your phone to Bluetooth adapter using Android Serial Emulator. If you are using the general Bluetooth adapter, the pairing code is 1234. For other adapters also, the pairing code should be 1234.

Step 5: Switch ON the IC1 -1 P DIP switch. If the switch is off, the 10pcs of LEDs connected to CD4094 will not work.

Step 6: Press a number from 0 to 255, and press ? , you will see LEDs responding as binary form of that number.

For example, press 1? glows one LED, i.e. the decimal to 8 bit binary conversion makes… 1= 00000001

or 255? glows all the LEDs, i.e. 255 = 11111111

or 3? glows only two LEDs, i.e. 3 = 00000011

Watch the video below and it will be more clear to you:

Related tutorials:


You can purchase this versatile Amarino shield at buildcircuit.net and Etsy. The store is owned and operated by the team which operates buildcircuit.com.

Amarino shield in use (2)Buy now button buy at etsy


Amarino shield- CD4094 control with Arduino- WITHOUT SMART PHONE

Fully assembled kit (4)

This is the first experiment for Amarino shield. If you do not know anything about Amarino toolkit or this shield please click on the following links:

  1. About Amarino toolkit
  2. About Amarino shield

You can get a list of other experiments at the end of this post.

This experiment has been derived from HEF4794_- Arduino_ Experiment.

This example makes the use of an LED Driver in order to control an almost endless amount of LEDs with only 4 Arduino pins. In this experiment, we use the CD4094 chip. Here, you can get the original version of this experiment: http://www.arduino.cc/en/Tutorial/LEDDriver . The Arduino team has used HEF4794.

An LED Driver has a shift register embedded that will take data in serial format and transfer it to parallel. It is possible to daisy chain this chip increasing the total amount of LEDs by 8 each time. You need to refer to datasheet for connecting more CD4094.

The code example you see here is taking a value stored in the variable dato and showing it as a decoded binary number. E.g. if dato is 1, only the first LED will light up; if dato is 255 all the LEDs will light up.

NOTE:  Switch ON the IC1 -1 P DIP switch. If the switch is off, the 10pcs of LEDs connected to CD4094 will not work.

Arduino Sketch: LINK

Amarino shield in use (2)

Related tutorials:


You can purchase this versatile Amarino shield at buildcircuit.net and Etsy. The store is owned and operated by the team which operates buildcircuit.com.

Amarino shield in use (2)Buy now button buy at etsy


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