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I am new to electronics, and I'm reading a book on embedded systems and bumped into an "Open Collector". I know that a transistor has a base, which acts like a switch for the current to flow from collector to emitter, but what does open collector mean?

What is it (in simple terms!), what does it do, and where to use it?

The picture below shows the one I got stuck on. For the record, don't ask me about what COM signal means.. The picture is something called a darlington transistor. (From the book "Introduction to ARM cortex M microcontrollers")

Darlington transistor

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    \$\begingroup\$ this has got to be a duplicate, right? \$\endgroup\$ – vicatcu Dec 26 '19 at 20:06
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    \$\begingroup\$ @vicatcu Probably \$\endgroup\$ – DKNguyen Dec 26 '19 at 20:07
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    \$\begingroup\$ think of a SPST switch ... one terminal is connected to ground ... the other terminal is connected to the output ... closing the switch connects the output to ground ... opening the switch disconnects the output from ground and allows the output to "float" \$\endgroup\$ – jsotola Dec 26 '19 at 20:28
  • \$\begingroup\$ The collector is not connected internally to Vcc but allows the collector to be connected to an arbitrary supply voltage through a load. The fly-back diode may also be connected across the load if this is inductive. \$\endgroup\$ – Chu Dec 26 '19 at 20:46
  • \$\begingroup\$ tell what you think COM means \$\endgroup\$ – Tony Stewart Sunnyskyguy EE75 Dec 26 '19 at 21:20
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It means the collector pin on the output NPN is open when in the HI state. As in it's not connected to a pull-up transistor and can actively drive the output HI.

That means it can only actively drive the output LO, or disconnect it. That means you have to provide a means to bring the output HI (like a pull-up transistor), or in some cases you don't care if the output is HI as much as you only care if it is conducting current or not(like to drive an LED), in which case you don't worry about a pull-up resistor and just connect the LED to it accordingly.

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  • \$\begingroup\$ @TonyM That doesn't change the fact that's what the "open" refers to for open collector means, particularly for the most base form of an open collector circuit which the OP's schematic is not. It's about as strict as what what "common" means in common collector and common emitter amplifiers. The "open" doesn't really refer to "the state of the output when the transistor is off" because then the OP could just as easily ask why is that the namesake and not when transistor is conducting? \$\endgroup\$ – DKNguyen Dec 26 '19 at 20:18
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An open collector means nothing is connected to the collector, the collector is left open.
With nothing connected, I mean from the view of the transistor or circuitery which is in front of this 'output'.
When the transistor is not conducting, the voltage of the output is either floating or driven by external components.
When the transistor is conducting, the output is 'shorted' to the emitter of the transistor. In OP's case, the output is 'shorted' to ground.
You have to 'externally' connect something to this open collector to make it useful, like e.g. a pull-up resistor.

The benefit of an open collector lies it the fact that when the transistor is not conducting, the voltage of the output is either floating or driven by other external components.
In this way, you can connect multiple open collector outputs to each other.

If you connect multiple push-pull driver outputs directly together, you will have a problem when one driver tries to push the output up (to e.g. Vcc) and another driver tries to pull down the output (to e.g. GND).

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The schematic you show is a partial schematic of a ULN2003A or similar Darlington driver array. COM is a common rail (typically) used for the catch (flyback) diodes when inductive loads are being switched.

The two collectors connected together do go to the diode so they're not completely open, but that diode does not normally conduct- only briefly when an inductive load is switched off, so ignore it for the purposes of this discussion.

A Darlington pair is sort of a compound transistor with very high current gain. The usual textbook depiction is two transistors connected thusly:

schematic

simulate this circuit – Schematic created using CircuitLab

The practical circuit in the ULN2003A includes resistors to make sure the gain is not excessively high and a parasitic diode is also shown.

The collectors in both the Darlington pair and the simple BJT are "open". If you drive the inputs with a (say) 0V/5V you won't see much voltage at the collector, they need a load from the collector to some positive rail (such as a pull-up resistor) to get substantial current to flow.

The open-collector (rather than having a resistor or some active circuit as a pull-up) allows to to use a higher voltage than the logic supply, for example, if the ratings allow. You can use an open-collector output ULN2003A to switch a 24V relay from a 5V or 3.3V logic level (since relays are inductive you'd tie COM to +24).

Many analog comparators have open-collector outputs- that allows outputs to be directly tied together with a single pull up resistor such that the output only goes high if all the transistors are off. That's useful, for example for making a window comparator which detects when a voltage is within a certain range.

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At first glace, the circuit you show looks a lot like a single channel of a ULN2003A 7-channel Darlington driver. Sticking with the ULN2003A, each of its channels uses a Darlington driver, a circuit where one transistor directly drives another transistor to get a combined current gain higher than the current gain of a single transistor. The COM diode in each channel is useful if the 7 open-drain drivers are each switching an inductive load, like a relay or a solenoid, and all 7 loads run from a common supply. Then the diodes are used to clamp the back emf of the inductive load.

With that to one side, let's answer your actual question...

Open-collector is a type of switched load driver circuit, along with open-emitter and push-pull. Open-collector and open-emitter are used if the switching component is a bipolar junction transistor (BJT) as collector and emitter are terminals of a BJT.

If a FET is used as the switch, the terms open-drain and open-source are used as those are the relevant terminals on a FET.

In a switched driver, the output transistors are either switched hard on or switched hard off, never partially conducting. They can be seen to act like simple on/off switches. In actuality, there's a lot more to the circuit behaviour than that simple summary but it lets us grasp the basics of what it does.

The comprehensive switching driver circuit is a push-pull output. This consists of two switching transistors - FETs in the example below.

enter image description here

Here, when one FET is on, the other one is off. As the diagram shows, this circuit has two driving states. (1) When the upper FET is on, the lower FET is off and the circuit is driving (supplying) current to its output at a 'high' voltage. (2) When the upper FET is off, the lower FET is on and the circuit is sinking (taking) current from its output at a 'low' voltage. Ideally, the 'high' voltage would be VDD and the 'low' voltage would be GND but the imperfect FETs have losses so not they vary away from that.

An open-collector driver circuit contains the lower transistor that sinks current but has no upper transistor to supply it. Those names are for a BJT circuit. When FETs are used, it's an open-drain driver circuit. As shown below, the push-pull FET circuit (left) has had the upper FET removed (middle). When the lower FET (middle) is on, current can flow through the transistor to GND. When the lower FET is off, there is no current flow and the output is said to be 'floating' or at high impedance. An external circuit must supply the current to flow through the lower FET. This could be a pull-up resistor (right).

enter image description here

Similarly, the open-source driver FET circuit has an upper transistor and no lower transistor. It can supply current to the output or be high impedance.

All three driver circuits are illustrated in these FET circuits.

enter image description here

There is plenty more you can read up yourself on the internet on these circuits. This should give you enough of the basics to find, understand and learn.

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