8/2/2019 Basic Scope Controls

1/3

c Scope Controls

//www.crypton.co.za/Tto%20know/Scopes/basic%20controls.html[4/27/2012 7:05:29 PM]

Oscilloscopes

In this section we will try to give you a brief introduction into how the modern oscilloscope works and its bascontrols. It is our intention to help you to have trust in this universal diagnostic tool. This introduction can in no wclaim to be complete with regards to the electronic details of such tool, the aim is only to inform you of those thinwhich are of importance for practical operation and use. Therefore many things are simplified in order to facilitate

understanding of the basic functions.

What is a oscilloscope: The oscilloscope is an electronic device with a screen, which is used to measurevoltage against time. With its very fast measuring capabilities it can detect very short ( in time) and intermitvoltage signals and freeze them on the screen before they disappear. As they say picture speaks a thousanwords, the oscilloscope paints a picture for us, on the screen, representing voltage versus time. Understandthose pictures or as we call them waveforms, is of utmost importance as to understanding the processes thhave created them.

The Scope screen: The oscilloscope screen has gone through some degree of evolution as the old screenswere cathode-ray tubes and the modern screens can be anything from LCD screens, picture tubes (as used inTVs and PC screens) or even plasma screens. There is a certain degree of difference between those and theway they represent a waveform. Due to the nature of LCD and PC displays the signal representation appearbe somewhat not as smooth as with normal tube. This is what we call digitizing. As you probably know, tPC screen is organized in rows and columns of little squire dots called - pixels. The very text you are readinnow is in fact made of series of pixels organized in such a way as to represent letters. If you magnify thosletters youll see the painted squire dots (pixels) next to each other. Most scopes today use this form ofrepresenting the waveforms as it is a small trade-off against the ability to capture, store, roll-back, expand, aeven save the waveforms. So if you are used to see waveforms on your scope and move to one of another ty

you may find the same waveform somewhat strange. Never the less, little practice and basic understanding isyou need to quickly get used to the new one.

Painting a picture: In order for us to understand the waveforms we see on the scope screen we need to knohow are they painted on it. As we have said before, the scope represents the signal in to directions. Voltagevalue is represented vertically and the time taken horizontally. Therefore the screen is divided in to a grid squires called divisions vertically and horizontally. Vertically - voltage in volts, milivolts, kilovolts and so oand horizontally time in seconds, milliseconds, microseconds and so on. Each direction of divisions can beto represent different values. So you can have 5v/div ( 5 volts per division ) representing voltage value of 5vyou have pattern that reaches to the top of the division, and 1s/div ( 1 second per division ) if the signal haslasted for 1sec. the pattern will reach the end of the division. The signal is painted pixel by pixel as it goes aany change in vertical direction represents the signal voltage value, and the time it took is representedhorizontally.

The Laboratory Scope: This is where the scopes were only used in the beginning, in the laboratories. Hencthe name. The old scopes had cathode-ray tubes and limited capabilities of conditioning of the measuredsignal. If a signal had only occurred once and it did not repeat for long time, one have to stare at the screen fa long time in order not to miss it. Now that is painful and time consuming. With the advance of electronicsand computers however, the modern lab scopes are much more sophisticated as they have much better

8/2/2019 Basic Scope Controls

2/3

c Scope Controls

//www.crypton.co.za/Tto%20know/Scopes/basic%20controls.html[4/27/2012 7:05:29 PM]

capabilities of capturing the signal and displaying it on the screen.

The Automotive Oscilloscope: This scope is essentially an ordinary scope, but with added capabilities andspecific signal pick-ups as to make operating with it and using it to diagnose todays vehicles faster and easiOne can still use an ordinary scope or a lab scope for such work, but setting time-base and triggers can besome times tedious and youll need those special signal pick-ups in order not to damage the scope inputs.get yourself the right tool for the job.

Basic Scope Controls: The two most important controls in the oscilloscope are the controls for change oftime-base (horizontally) and change of voltage range ( vertically). Setting up those two properly, makes thedifference between seeing a waveform and blank screen! While doing automotive diagnostics, we usually kn(more or less) what is the voltage of the signal we want measure, setting the time-base ( time/div ) can be mdifficult in order to capture the waveform we need. Good place to start is in the middle of the time-baserange and then once you see a waveform appearing on screen, change the controls accordingly to get a goodpractical view of the measured signal. For most purposes setting the time-base to 20ms/div ( 20 millisecondsper division ) and 10v/div for the voltage range will get you a waveform and then the controls can bereadjusted to suit the signal strength and time.

Channels: We can ( for simplicity) look at the scope channels as its inputs. One channel scope can displayonly one waveform on the screen at a time because have one input. Now if we combine two channels with oscreen, well have two inputs and well get two waveforms that we can compare on to the same screen. Mos

oscilloscopes have two channels, although 3, 4 and even more channels in one scope ( depending on the mod) can be found. Quite frankly the more the better as it gives the scope more versatility and comparing power

Triggering: Another control that we use in the oscilloscope is the ability to start measuring when a particuevent occurs. This is called triggering. As the name suggest triggers are conditions which when met willtrigger the scope to start the measurement. Now, this is very useful, if we want to separate particular event itime and also helps to get steady waveform that starts always from the same time when we measure repetitivevents. Most events in the ignitions system are repetitive as we know already. Triggering can be done topositive and negative values, and to rising and falling values. Oscilloscopes usually have internal trigger abi

http://www.crypton.co.za/Tto%20know/Scopes/grid.gif

8/2/2019 Basic Scope Controls

3/3

c Scope Controls

//www.crypton.co.za/Tto%20know/Scopes/basic%20controls.html[4/27/2012 7:05:29 PM]

as well as external.

1. Internal Trigger: Internal triggering is when we adjust the scope to trigger when the measured signalreaches certain value. i.e. 1v for instance. So when the signal is under 1v the screen will stay still (nomeasurement displayed) but as soon as it reaches the trigger point ( in this case 1v), the scope will startplotting the waveform on the screen. In other words it will show us what is happening with the signal ait reaches or exceeds the trigger level of 1v.. The internal triggering is only done for the scope channel are working with.

2. External Trigger: External triggering is when we use external ( other to the one measured with the scochannel) signal. This external signal have to be monitored (measured) through another channel of thescope and when a trigger event occurs in that signal this event will trigger thefirst channel to start plottthe waveform of its own measured signal. We may or may not want to see the (external) triggering sigfrom the second channel. It is a matter of adjustment what you want to see on the screen.

3. Free Run (no trigger): This is when we leave the scope to plot the measured signal in a waveform anddont interfere with how the waveform is displayed. This may be ok for some repetitive AC signals butmost DC signals and especially for ignition related signals we need to trigger as to see the eventsoccurring from the very beginning. Otherwise youll get a waveform that starts anywhere on the time-bwith no guarantee that it will start again there the next time it occurs.

To conclude: The Oscilloscope is the fastest, most versatile and the only tool that will let you see the signal ats variations under measurement with respect to the time it took. Those abilities make this tool, indispensable, if nhe most important of the arsenal of automotive technician. Ever seen a doctor trying to predict the sex of a child

before birth, without ultrasound machine. He may just get it right sometimes, but never 100%.

In addition to the ability to plot waveforms, most modern computer based oscilloscopes have many other usefufeatures as calculating the minimum and maximum voltage peak of a the signal, conversions from frequency in toRPM, saving the waveforms and recording a "movie" of consecutive waveforms for a later review, etc, etc.Specialised Scopes as the ignition oscilloscope ( depending on the manufacturer and model ) can have other

mprovements as automatically setting the time/voltage bases for measurements of different signals i.e. "fuel injector "ignition primary" . This saves you time and ensures the waveform is always captured correctly.

Automotive Equipment - in tune with the Future

Crypton Diagnostic Equipment Home

http://www.crypton.co.za/Crypton/crypton%20tune%20up.htmlhttp://www.crypton.co.za/index.htmhttp://www.crypton.co.za/index.htmhttp://www.crypton.co.za/http://www.crypton.co.za/Crypton/crypton%20tune%20up.html