HC-SR04 sensor
Remember these guys? HC-SR04 ultrasonic rangefinders. Colin used to have three of them, but I’ve recently been reworking his sensor layout. I’m starting by adding five more sensors for a total of eight. Colin’s Arduino has just barely enough free pins to accommodate eight sensors, but I don’t want to spend all of my available pins on sensors. That would leave me no room to expand. Further, I’m not totally sure eight sonar sensors will be enough. My HC-SR04 sensors have a range of about 15 degrees, so it would take 24 sonar sensors to cover 360 degrees. I don’t know if that will be necessary, but I’d like to have the option.
There are a couple of ways to do this. The simplest would probably be to use a shift register. Shift registers allow you to use three I/O pins to control more than a thousand additional pins, but operating them involves some computing overhead and the Arduino still has to be involved in every sensor reading operation.
An Atmel ATtiny84
The method I’ve chosen is to use a separate microcontroller, an ATtiny84, to handle the sonar sensors. The Aduino tells the ATtiny that it needs new sensor readings. Then it goes and performs some other computations while the ATtiny pings its sensors. Then, when the new sensor data is ready, the ATtiny sends back the new readings all at once. Using this scheme, the Arduino doesn’t have to spend processor time reading sensors. Instead it can focus on other problems. Also, since it can communicate with the Arduino via I2C, it only requires 2 I/O pins! Here’s what Colin looks like with his new sonar layout.
Colin with his new sonar ring
As with my earlier post on Raspberry Pi to Arduino communication, there’s several steps to this process. Luckily it’s a lot simpler this time.
- We’ll start by defining a communication protocol
- Then we’ll look at the physical layout of my sonar controller
- Lastly we’ll go through the code
- Then we’ll wrap it up
The Communication Protocol
The communication protocol is going to be very similar to the one that I outlined for communicating between a Raspberry Pi and an Arduino, only simplified. Basically, the Arduino tells the ATtiny when it needs updated sonar readings. The ATtiny then pings all of its sensors and sends back the readings when it’s done. This is how it works:
- The Arduino sends a byte to the ATtiny
- The byte has no meaning, it’s just a flag to signal the ATtiny to ping its sensors
- The ATtiny pings its sensors
- The ATtiny sends its readings back to the Arduino as 16 bytes
- The Arduino assembles the bytes into 8 16-bit ints
One other difference with the Raspberry Pi to Arduino protocol is that we’ll be using I2C instead of serial. If you’re not familiar with I2C I’d suggest reading up on it. Sparkfun has a great tutorial.
That’s really all there is to it! The protocol is simple, but there’s some fiddly details to work out in the code.
The Sonar Controller
My ATtiny84-based sonar controller
My sonar controller basically consists of an ATtiny84, with eight inputs for HC-SR04 ultrasonic rangefinders. If you’re interested in making your own, you can download my eagle files for the schematic, board layout, and the gerber files for fabbing the PCB. The gerbers are formatted for fabrication by OSH Park, which I highly recommend for low-volume jobs.
The controllers each have two sets of inputs for power and I2C communication so multiple controllers can be chained together on the same bus. Note that there are two spots for 4.7 kOhm resistors on each controller. These are pull-ups for the I2C buses. If you’re chaining multiple controllers together, only one of them needs pull-up resistors. The resistor spots on the other controllers can be left empty.
I also designed a laser-cut frame to hold the sonar sensors and controller, as well as some fittings to attach the whole business to Colin. The design is pictured below, and you can download the SVG files to make your own parts here.
Colin with his new sensor arrangement and fittings
If you’d rather not fab a custom circuit board, you can set it up on a breadboard as shown below. It’s not particularly useful on a breadboard, but it will allow you to experiment with and test it.
Breadboard wiring for ATtiny sonar controller
The Code!
ATtiny Code
Let’s start out with a couple of preliminaries. First, for I2C communication I’m using the TinyWireS and TinyWireM libraries. We need our ATtiny to perform as both master and slave, but there is no existing library that allows this. Fortunately there’s a way to hack around this problem.
I’m also using the NewPing library. The NewPing library doesn’t work with ATtinies, but there’s a hack for this too. You just need to comment out the functions for Timer2 and Timer4 because the ATtiny does not have these timers.
You can find the complete program for the ATtiny here. If you’re not familiar with how to program ATtinies, I’d suggest going through this very thorough tutorial.
Initiating A Sensor Update
The function below pings the eight sonar sensors and records the ping times in microseconds.
void updatePingTimes(uint8_t bytes)
{
TinyWireS.receive();
for (int i = 0; i < NUM_SONAR; i++)
{
pingTimes[i] = sonar[i].ping();
}
sendTimes();
}
The function above is invoked using an interrupt when the ATtiny receives a byte from the Arduino. The line below is called in the setup() function to tell the ATtiny to generate an interrupt and call the updatePingTimes() function whenever data is received from the Arduino.
TinyWireS.onReceive(updatePingTimes);
Sending Data Back To The Arduino
When the sonar sensors have been updated, the sendTimes() function is called to send the updated ping times back to the Arduino. It is important to note that the ATtiny must be functioning as a slave in order to use the onReceive() function. To send data back to the Arduino, the ATtiny must function as a master. This makes the sendTimes() function a bit more complicated.
void sendTimes()
{
// clear the I2C registers
USICR = 0;
USISR = 0;
USIDR = 0;
// start I2C with ATtiny as master
TinyWireM.begin();
// transmit ping times to Arduino
TinyWireM.beginTransmission(MASTER_ADDRESS);
for (int i = 0; i < NUM_SONAR; i++)
{
int thisTime = pingTimes[i];
if (thisTime == 0) thisTime = (double)MAX_DISTANCE / speedOfSound;
uint8_t firstByte = thisTime & 0xFF;
uint8_t secondByte = (thisTime >> 8) & 0xFF;
TinyWireM.write(firstByte);
TinyWireM.write(secondByte);
}
TinyWireM.endTransmission();
// clear I2C registers again
USICR = 0;
USISR = 0;
USIDR = 0;
// put ATtiny back in slave mode
TinyWireS.begin(OWN_ADDRESS);
}
As I said before, I don’t know of any library that allows an ATtiny to function as both master and slave. Fortunately we can hack our way around this problem by clearing the ATtiny’s I2C registers and restarting communication in master mode. After we’ve transmitted the ping times back to the Arduino we need to clear the I2C registers again and put the ATtiny back in slave mode so it can be ready for the next request from the Arduino. I don’t mind telling you it took me a lot of time with the ATtiny’s datasheet to figure out how to make that work.
Arduino Code
For reference you can find the complete program for the Arduino here. To get things going we need to include the Wire library and put the following two lines in the setup() function:
// begin communication with sonar controller Wire.begin(OWN_ADDRESS); Wire.onReceive(updateDistances);
Adding the onReceive() function is particularly important because it allows the Arduino to do other processing tasks while the ATtiny pings its sensors. When the ATtiny sends data it generates an interrupt, the Arduino stops what it’s currently doing and receives the new data, then goes back to whatever it was doing before.
Receiving Data
The updateDistances() function works as follows:
// updates sonar distance measurements when a new reading is available
void updateDistances(int bytes)
{
for (int i = 0; i < NUM_SONAR; i++)
readSonar(i);
distancesRead = true;
}
// reads the distance for a single sonar sensor
// expects to receive values as ints broken into 2 byte pairs,
// least significant byte first
void readSonar(int index)
{
int firstByte = Wire.read();
int secondByte = Wire.read();
sonarDistances[index] = ((double)((secondByte << 8) | firstByte)) * speedOfSound * 0.5;
}
Notice that the sonar distance is multiplied by 0.5 when it’s added to the sonarDistances array. This is because the ATtiny returns the total time of flight for the ultrasonic ping. The ping needs to go from the sensor, to the obstacle, and back. This means multiplying the ping time by the speed of sound would result in twice the distance between the obstacle and the sensor.
Requesting An Update
Fortunately, requesting an update is pretty simple. The Arduino just needs to send a byte, any byte, to the ATtiny to let it know it needs new sensor readings.
// requests a sonar update from the sonar controller at the given address
// by sending a meaningless value via I2C to trigger an update
void requestSonarUpdate(int address)
{
Wire.beginTransmission(address);
Wire.write(trig);
Wire.endTransmission();
}
After this function executes, the Arduino can perform other processing tasks until the ATtiny sends back updated sonar readings.
Going Further
There are a number of ways to solve the problem of coordinating large numbers of sonar sensors, and the above method is only one possibility. It takes a long time to update sonar sensors, up to 15 milliseconds for 8 sensors. For an Arduino running at 16 MHz, that’s 240,000 processor cycles. So it’s advantageous to use a method that allows the Arduino to do something else while the sensors are being updated. My method does this, but one could also take the Arduino out of the loop entirely and have the Raspberry Pi talk to the sonar controller directly. It would be interesting to implement this method and compare it to the one presented above.