What is an ECG?

The ECG is a valuable, non-invasive diagnostic tool which was first put to clinical use in 1913 with Einthoven's invention of the string galvanometer.The results below show a reproduction of one of Einthoven's original traces.

Establishing the correspondence between the ECG trace and the electrical events in the heart is known as the inverse problem of electrocardiology: solving for the electric sources from the potential generated by those sources on the surface of the body.

Description of the ECG application

DrDAQ ECG project setup

Sample results

Results with L1 and L2 leads on chest

Results with L1 and L2 leads on wrists

ECG electronic circuit description

ECG circuit diagram - view a larger diagram suitable for printing

Input cables and circuitry

Because of the safety issues associated with electrically connecting a person to an electronics device that runs off a significant power source, diode protection was added to the inputs to the amplifier. The circuit shown above only runs off of two 9-Volt batteries, which themselves don't constitute a "significant power source", however an oscilloscope or computer to which the output of the amplifier is connected will in general be powered by the line voltage from a wall socket. If for some reason there is a power surge that causes something catastrophic to happen in the oscilloscope or computer, it is imaginable that the line voltage could be transmitted through the amplifier to its inputs. Although this scenario is unlikely, the diode connections to ground should in principle route the current to ground since it takes only 0.6 Volts across the diode before it acts as a short circuit. The 0.6 Volts is much larger than the electrical signals coming from the heart, so this shouldn't affect the performance of the circuit. Also, you need two oppositely oriented diodes for each input - one to carry current during positive voltage swings, and one for negative voltage swings. Alternatively, to improve safety the circuit could be redesigned and the protection diodes replaced with an optoisolator circuit - this would provide complete galvanic isolation (upto several thousand Volts) between the electrodes and the power supply.

Output cable and circuitry

The output part of the circuit is modified relative to the Scientific American article so that the output could be connected to the DrDAQ ADC which has a dynamic range for voltages between 0 and 5 Volts. This is not well matched to the ECG signal which has both positive and negative-going pulses. Consequently it was necessary to AC-couple the output of the amplifier with the 1µF capacitor shown, and add a pull-up resistor connected to the +9 Volt supply to bring the DC level to a positive value of about 2 Volts (see sample traces above). A 680k Ohm resistor was used since the resistance across the ADC (forming the other leg of the voltage divider) measured to be about 180k Ohms. (An ADC with bi-polar inputs could be used instead of the DrDAQ so that AC-coupling is not necessary - see pc oscilloscopes for suitable products)

Power supply

Grounding and noise reduction

However, as noted in the safety issues section, one should be very wary about connecting a home-built circuit to something that is running off a significant power source. In principle, one can more safely read out the circuit using a laptop computer that is running off its battery. However, this leaves the laptop's ground floating, and without a good ground connection it was found that there was a tremendous amount of noise, and the ECG signal became completely obscured. If the circuit can be connected to a good ground connection then using a battery-powered laptop should work well.

As an enhancement to this project additional noise reduction measures could be investigated.

Data acquisition

The DrDAQ package consists of a data acquisition card that has inputs for digitising light, sound, temperature and voltage signals and is connected to (and derives power from) the parallel port of any personal or laptop computer. Windows based software is used to display the digitised data in time-series format, as would be obtained on an oscilloscope (as shown in the traces above.)

If required it is possible to use other Pico Technology pc oscilloscope products instead of the DrDAQ data logger.

Safety issues

As mentioned in the section on the electronic circuit, when you connect your body to any electronic device, you must be much more careful than you usually are with your standard home electronics, because it can be extremely easy to cause a serious and even fatal electric shock.

Professionally built medical devices are built with significant overvoltage protection so that line power glitches do not represent a hazard to patients - for this application diodes are used to provide limited over-voltage protection. To further increase safety an optoisolator intergrated circuit could be added to the existing circuit so that the subject is completely isolated from the power supply.

You should not attempt to use such a setup as that described here unless you are knowledgeable about and comfortable with using electricity in a safe and controlled manner.

References

• Mathematical Physiology, by J. P. Keener and J. Sneyd, Springer-Verlag.
• The Initiation of the Heartbeat, by D. Nobel, Oxford.
• Physics with Illustrative Examples from Biology and Medicine: Electricity and Magnetism (Vol. 3), by G. B. Benedek and F. M. H. Villars, Addison-Wesley, Chapter 2.
• The Electrocardiogram as an Example of Electrostatics, by R. K. Hobbie, Am. J. Phys. 42, 824 (1973).

Further Information

• Explore the key elements of the Electrocardiogram at the Nobel e-Museum
• Visit the DrDAQ data logger website. for more information on the low-cost data logger and its many applications.
• Details of other oscilloscope products that can used instead of the DrDAQ.