Peak dca55, Atlas DCA55 User Manual

Peak Atlas DCA

Semiconductor Component Analyser

Model DCA55

Designed and manufactured with pride in the UK

User Guide

©

Peak Electronic Design Limited 2000/2014

In the interests of development, information in this guide is subject to change without notice - E&OE

GB55-11

Atlas DCA User Guide September 2014 – Rev 11

Page 2

Want to use it now?

We understand that you want to use your Atlas DCA right now. The

unit is ready to go and you should have little need to refer to this user

guide, but please make sure that you do at least take a look at the

notices on page 4!

Contents Page

Introduction....................................................................................3

Important Considerations...............................................................4

Analysing semiconductors .............................................................5

Diodes......................................................................................7

Diode Networks .......................................................................8

LEDs........................................................................................9

Bicolour LEDs .......................................................................10

Bipolar Junction Transistors (BJTs).......................................11

Digital Transistors..................................................................18

Enhancement Mode MOSFETs .............................................19

Depletion Mode MOSFETs ...................................................20

Junction FETs (JFETs) ..........................................................21

Thyristors (SCRs) and Triacs.................................................22

Taking care of your Atlas DCA....................................................23

Battery replacement ...............................................................23

Self Tests ...............................................................................24

Appendix A - Technical Specifications........................................25

Appendix B - Warranty Information............................................26

Appendix C - Disposal information .............................................27

Atlas DCA User Guide September 2014 – Rev 11

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Introduction

The Peak Atlas DCA is an intelligent semiconductor analyser that offers great
features together with refreshing simplicity. The Atlas DCA brings a world of
component data to your fingertips.

Summary Features:

• Automatic component type identification

 Bipolar transistors
 Darlington transistors
 Enhancement Mode MOSFETs
 Depletion Mode MOSFETs
 Junction FETs
 Low power sensitive Triacs
 Low power sensitive Thyristors
 Light Emitting Diodes
 Bicolour LEDs
 Diodes
 Diode networks

• Automatic pinout identification, just connect any way round.

• Special feature identification such as diode protection and resistor

shunts.

• Gain measurement for bipolar transistors.

• Leakage current measurement for bipolar transistors.

• Silicon and Germanium detection for bipolar transistors.

• Gate threshold measurement for Enhancement Mode MOSFETs.

• Semiconductor forward voltage measurement for diodes, LEDs and

transistor Base-Emitter junctions.

• Automatic and manual power-off.

Atlas DCA User Guide September 2014 – Rev 11

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Important Considerations

Please observe the following guidelines:

•

This instrument must NEVER be connected to powered
equipment/components or equipment/components with any
stored energy (e.g. charged capacitors). Failure to comply
with this warning may result in personal injury, damage to
the equipment under test, damage to the Atlas DCA and
invalidation of the manufacturer’s warranty.

•

The Atlas DCA is designed to analyse semiconductors that
are not in-circuit, otherwise complex circuit effects will
result in erroneous measurements.

•

Avoid rough treatment or hard knocks.

•

This unit is not waterproof.

•

Only use a good quality Alkaline battery.

Atlas DCA User Guide September 2014 – Rev 11

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Analysing Components

The Atlas DCA is designed to analyse discrete,
unconnected, unpowered components. This
ensures that external connections don’t influence
the measured parameters. The three test probes can be
connected to the component any way round. If the component has
only two terminals, then any pair of the three test probes can be used.

The Atlas DCA will start component
analysis when the on-test button is
pressed.

Depending on the component type, analysis may take a few seconds to
complete, after which, the results of the analysis are displayed. Information is
displayed a “page” at a time, each page can be displayed by briefly pressing the
scroll-off button.

The arrow symbol on the display indicates that more pages are available
to be viewed.

Although the Atlas DCA will switch itself off if left unattended, you
can manually switch the unit off by holding down the scroll-off
button for a couple of seconds.

Atlas DCA55 Rx.x

is analysing....

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If the Atlas DCA cannot detect any
component between any of the test
probes, the following message will be
displayed:

If the component is not a supported
component type, a faulty component or
a component that is being tested in­circuit, the analysis may result in the
following message being displayed:

Some components may be faulty due to
a shorted junction between a pair of the
probes. If this is the case, the following
message (or similar) will be displayed:

If all three probes are shorted (or very
low resistance) then the following
message will be displayed:

It is possible that the Atlas DCA may detect one or more diode
junctions or other component type within an unknown or faulty part.
This is because many semiconductors comprise of PN (diode)
junctions. Please refer to the section on diodes and diode networks for
more information.

No component
detected

Unknown/Faulty
component

Short circuit on
Green Blue

Short circuit on
Red Green Blue

Atlas DCA User Guide September 2014 – Rev 11

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Diodes

The Atlas DCA will analyse almost any type of
diode. Any pair of the three test clips can be
connected to the diode, any way round. If the
unit detects a single diode, the following
message will be displayed:

Pressing the scroll-off
button will then display the pinout for
the diode. In this example, the Anode of
the diode is connected to the Red test
clip and the Cathode is connected to the
Green test clip, additionally, the Blue
test clip is unconnected. The forward
voltage drop is then displayed, this gives
an indication of the diode technology. In
this example, it is likely that the diode is
a silicon diode. A germanium or
Schottky diode may yield a forward
voltage of about 0.25V. The current at
which the diode was tested is also
displayed.

Note that the Atlas DCA will detect only one diode even if two diodes
are connected in series when the third test clip is not connected to the
junction between the diodes. The forward voltage drop displayed
however will be the voltage across the whole series combination.

The Atlas DCA will determine that the diode(s) under test is an LED
if the measured forward voltage drop exceeds 1.50V. Please refer to
the section on LED analysis for more information.

Diode or diode
junction(s)

RED GREEN BLUE
Anod Cath

Forward voltage
Vf=0.67V

Test current
If=4.62mA

Atlas DCA User Guide September 2014 – Rev 11

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Diode Networks

The Atlas DCA will intelligently identify popular types of
three terminal diode networks. For three terminal devices
such as SOT-23 diode networks, the three test clips must all
be connected, any way round. The instrument will identify the type of diode
network and then display information regarding each detected diode in
sequence. The following types of diode networks are automatically recognised
by the Atlas DCA:

Both cathodes connected
together, such as the BAV70
device.

Anodes of each diode are
connected together, the
BAW56W is an example.

Here, each diode is connected
in series. An example is the
BAV99.

Following the component identification,
the details of each diode in the network
will be displayed.

Firstly, the pinout for the diode is
displayed, followed by the electrical
information, forward voltage drop and
the current at which the diode was
tested. The value of the test current
depends on the measured forward
voltage drop of the diode.

Following the display of all the details for the first diode, the details of the
second diode will then be displayed.

Common cathode
diode network

Common anode
diode network

Series
diode network

Pinout for D1...

RED GREEN BLUE
Cath Anod

Forward voltage
D1 Vf=0.64V

Atlas DCA User Guide September 2014 – Rev 11

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LEDs

An LED is really just another type of diode, however, the
Atlas DCA will determine that an LED or LED network has
been detected if the measured forward voltage drop is larger
than 1.5V. This also enables the Atlas DCA to intelligently
identify bicolour LEDs, both two-terminal and three-terminal varieties.

Like the diode analysis, the pinout, the
forward voltage drop and the associated
test current is displayed.

Here, the Cathode (-ve) LED terminal is
connected to the Green test clip and the
Anode (+ve) LED terminal is connected
to the Blue test clip.

In this example, a simple green LED
yields a forward voltage drop of 1.92V.

The test current is dependant on the
forward voltage drop of the LED, here
the test current is measured as 3.28mA.

Some blue LEDs (and their cousins, white LEDs) require high
forward voltages and may not be detected by the Atlas DCA.

LED or diode
junction(s)

RED GREEN BLUE
Cath Anod

Forward voltage
Vf=1.92V

Test current
If=3.28mA

Atlas DCA User Guide September 2014 – Rev 11

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Bicolour LEDs

Bicolour LEDs are automatically identified. If your LED has 3
leads then ensure they are all connected, in any order.

A two terminal bicolour LED consists of two LED chips which
are connected in inverse parallel within the LED body. Three terminal bicolour
LEDs are made with either common anodes or common cathodes.

Here a two terminal LED
has been detected.

This message will be
displayed if the unit has
detected a three terminal
LED.

The details of each LED in the package
will then be displayed in a similar way
to the diode networks detailed earlier.

The pinout for the 1st LED is displayed.
Remember that this is the pinout for just
one of the two LEDs in the package.

Interestingly, the voltage drops for each
LED relate to the different colours
within the bicolour LED. It may
therefore be possible to determine which
lead is connected to each colour LED
within the device. Red LEDs often have
the lowest forward voltage drop,
followed by yellow LEDs, green LEDs
and finally, blue LEDs.

Two terminal
bicolour LED

Three terminal
bicolour LED

Pinout for D1...

RED GREEN BLUE
Anod Cath

Forward voltage
D1 Vf=1.98V

Test current
D1 If=3.22mA

Atlas DCA User Guide September 2014 – Rev 11

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Bipolar Junction Transistors (BJTs)

Bipolar Junction Transistors are simply “conventional”
transistors, although variants of these do exist such as
Darlingtons, diode protected (free-wheeling diode), resistor
shunted types and combinations of these types. All of these
variations are automatically identified by the Atlas DCA.

Bipolar Junction Transistors are
available in two main types, NPN and
PNP. In this example, the unit has
detected a Silicon PNP transistor.

The unit will determine that the
transistor is Germanium only if the base­emitter voltage drop is less than 0.55V.

If the device is a Darlington transistor (two BJTs connected
together), the unit will
display a similar
message to this:

Note that the Atlas DCA will determine that the transistor under test is

a Darlington type if the base-emitter voltage drop is greater than

1.00V for devices with a base-emitter shunt resistance of greater than
60kΩ or if the base-emitter voltage drop is greater than 0.80V for
devices with a base-emitter shunt resistance of less than 60kΩ. The

measured base-emitter voltage drop is displayed as detailed later in
this section.

PNP Silicon
Transistor

PNP Germanium
Transistor

NPN Darlington
Transistor

Atlas DCA User Guide September 2014 – Rev 11

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Pressing the scroll-off button will result in the transistor’s pinout being
displayed.

Here, the instrument has identified that
the Base is connected to the Red test
clip, the Collector is connected to the
Green test clip and the Emitter is
connected to the Blue test clip.

Transistor Special Features

Many modern transistors contain additional special features. If the Atlas DCA
has detected any special features, then the details of these features are
displayed next after pressing the scroll-off button. If there are no special
features detected then the next screen will be the transistor’s current gain.

Some transistors, particularly CRT
deflection transistors and many large
Darlingtons have a protection diode
inside their package connected between
the collector and emitter.

The Philips BU505DF is a typical example of a diode protected bipolar
transistor. Remember that protection diodes are always internally connected

between the collector and the emitter so that they are
normally reverse biased.

For NPN transistors, the anode of the diode is connected to
the emitter of the transistor. For PNP transistors, the anode
of the diode is connected to the collector of the transistor.

RED GREEN BLUE
Base Coll Emit

Diode protection
between C-E

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Additionally, many Darlingtons and a few non-Darlington transistors also have
a resistor shunt network between the base and emitter of the device.

The Atlas DCA can detect the resistor shunt if it has a
resistance of typically less than 60kΩ.

The popular Motorola TIP110 NPN Darlington
transistor contains internal resistors between the base
and emitter.

When the unit detects the presence of a
resistive shunt between the base and
emitter, the display will show:

Additionally, the Atlas DCA will warn
you that the accuracy of gain
measurement (h

FE

) has been affected by

the shunt resistor.

It is important to note that if a transistor does contain a base-emitter

shunt resistor network, any measurements of current gain (hFE) will be
very low at the test currents used by the Atlas DCA. This is due to the
resistors providing an additional path for the base current. The
readings for gain however can still be used for comparing transistors
of a similar type for the purposes of matching or gain band selecting.
The Atlas DCA will warn you if such a condition arises as illustrated
above.

Resistor shunt
between B-E

hFE not accurate
due to B-E res

Atlas DCA User Guide September 2014 – Rev 11

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Faulty or Very Low Gain Transistors

Faulty transistors that exhibit very low gain
may cause the Atlas DCA to only identify one
or more diode junctions within the device. This
is because NPN transistors consist of a
structure of junctions that behave like a
common anode diode network. PNP transistors
can appear to be common cathode diode
networks. The common junction represents the base terminal. This is normal

for situations where the current gain is
so low that it is immeasurable at the test
currents used by the Atlas DCA.

Please note that the equivalent diode pattern may not be correctly

identified by the Atlas DCA if your transistor is a darlington type or
has additional diode(s) in its package (such as a collector-emitter
protection diode). This is due to multiple pn junctions that cannot be
uniquely analysed.

In some circumstances, the unit may not be able to deduce anything sensible
from the device at all, in which case you will see either of these messages:

B

C

E

Common anode
diode network

Unknown/Faulty
component

No component
detected

Atlas DCA User Guide September 2014 – Rev 11

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Current Gain (h

FE

)

The DC current gain (hFE) is displayed
after any special transistor features have
been displayed.

DC current gain is simply the ratio of the
collector current (less leakage) to the
base current for a particular operating
condition. The Atlas DCA measures hFE
at a collector current of 2.50mA and a
collector-emitter voltage of between 2V
and 3V.

The gain of all transistors can vary
considerably with collector current,
collector voltage and also temperature.
The displayed value for gain therefore
may not represent the gain experienced
at other collector currents and voltages.
This is particularly true for large
devices.

Darlington transistors can have very high gain values and more variation of
gain will be evident as a result of this.

Additionally, it is quite normal for transistors of the same type to have a wide
range of gain values. For this reason, transistor circuits are often designed so
that their operation has little dependence on the absolute value of current gain.

The displayed value of gain is very useful however for comparing transistors of
a similar type for the purposes of gain matching or fault finding.

Current gain
h

=126

Test current
Ic=2.50mA

I

C

=2.5mA

I

-I

(I = leakage
current)

C

Cleak

Cleak

h

FE

=

I

B

I

B