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If you look at the final expression, I think the line over the expression means "active low", or low voltage is 1. (Not exactly - if you're talking about pins on a chip, yes, the overbar means active low. In this case, the overbar means 'not'.
Mystic Pixel) Invert it, makes it active high:
NOT ( (A AND B) OR (C AND D) )
and apply Demorgan's, you get a wired AND:
NOT (A AND B) AND NOT (C AND D)
The gates he is interfaceing are NAND gates, and that fits:
(A NAND B) AND (C NAND D)
So this source says AND even though it labels it OR. (No - he uses NANDs because it's active low.
Mystic Pixel) Well, maybe we need a better source! Here is one:
"They may be connected to other open-drain outputs to implement active-low wired-OR or active-high wired-AND functions."
Hmmm. Somebody else pick it up from here. PLEASE show us your source on this page, no more "because this is correct". If no one can verify it, then well-meaning people will keep "fixing" it.
Dlotts04:06, 20 September 2006 (UTC)reply
A large part of the problem is the mis-application of "logic 1". Logic 1 may be 5V, 12V, 0V, 18V, 3.7V -- the voltage doesn't matter. By saying "logic 1", we just mean "the state that represents the presence of a bit." (That hardwaresecrets page claims '1' means '5V', which is only true in an active-high TTL logic environment.)
Now. About the word "active". "Active low" means that the low voltage state represents Logic 1, while the normal "Active high" method means that the higher of the two voltages represents Logic 1. To be frank, it doesn't mean that much -- it's just a difference in how you interpret the voltage levels.
With that in mind, it's easier to talk about circuits in terms of "enabled" and "disabled" (this is really what '1' and '0' meant, before people started thinking '1' means 'higher voltage' and '0' means 'lower voltage'.) If you think of things this way, 'active-low' circuits are easier to handle, because the only difference is that the 'enabled' state is represented by the lower voltage instead of the higher one.
This brings us to the central point of open-drain (and open-collector) devices. In normal devices, the output is connected to the associated voltage in both the enabled and disabled states. When the output is enabled, it is driven by the +Vcc, and when disabled, it's grounded (switch those for active-low!) However, in OD/OC devices, when the output is disabled, it is not driven by a voltage source or connected to ground! Instead, it presents a high impedance to connected circuitry -- it behaves like it is disconnected, or "open".
If you think about things in these terms, a NAND gate can be thought of as a device that converts active-high to active-low. When both inputs are enabled/higher-voltage, the output is enabled/lower-voltage. Otherwise, the output is disabled (in an open-collector device, this means 'open'.) Make sense? (This might get confusing, because when you're doing a truth table, the output is said to be '1' for the inputs {0,0}, {0,1}, and {1,0}. This indicates the 'higher-voltage' state, which is 'enabled' for active-high logic, but 'disabled' if you're thinking active-low.)
This is why we're using NAND gates to drive the bus, instead of AND gates (and, I think, this is why many busses use an active-low type standard.) Let's do an example.
I build this circuit with regular (not open-drain) devices. For most of the possible input conditions, both NAND gates output higher-voltage ('1', but the bus is active-low, so it's really 'disabled' in those terms.) Since these are regular devices, the output pins are connected to the higher-voltage supply, +Vcc. Now, if A and B both go to 1 (note that the input circuitry is active-high!), then the output of the first NAND goes to '0' -- (but it's active-low, so it's like the output is being 'enabled'). In order to do this, the top NAND connects the output pin to Ground. Now, since the lower gate is still connecting the output to +Vcc, the bus is connected to both ground and Vcc at the same time! The state of the bus is unpredictable at best (worst case, you've shorted your power supply!) Open-drain/Open-collector devices allow us to avoid this.
Now, I rebuild the circuit with open-drain logic gates (note the *), and a pull-up resistor. When the gates are outputting '1', they are 'disabled' (active-low!) and thus, they are 'open' as explained above. As long as nothing is drawing current from the bus, there is no voltage drop across the resistor, and the bus voltage is +Vcc (5V in this case.) The important point is that the gates themselves are not holding the bus at +Vcc. That is being done by the resistor. If I turn on A and B, the first gate 'enables' and goes low, so it is connected to ground. Now, since the bus is shorted to ground, there is 0V on it (all the voltage from the supply goes away, because the current flow creates a voltage drop across the resistor.) This works with open-drain gates because the second gate doesn't try to drive the bus high!
This is (one of) the benefit(s) of open-collector devices. They act as a wired OR in active low logic (using NAND gates, as above.) I just realized the source of the confusion - if you're looking at them from the viewpoint of active high logic, it behaves like a wired AND, since the bus will be '1' only when all the outputs are '1'. While this isn't wrong per se, thinking of it in those terms leads to confusion, because what's really happening is that the bus is being driven low when at least one of the gates connects it to ground.
The article page itself is really confusing, but I can't fix it now. I hope this explanation clears things up. None of my textbooks have a good reference on this, it was something one of my professors explained a few years ago. Here are some other pages I found -- An open-collector BJT behaves the same as an open-drain FET, so the explanations more or less apply to both.
"As there is no pull-up resistor internal to the device an unconnected O/C output will give indeterminate voltage levels if viewed with a CRO or meter. O/C outputs can be connected together to provide greater current sinking ability or as a current driven OR gate."
"[O]pen collector output is simply where a transistor either presents a current path to ground, or not."
This goes back to what I was saying about enabled/disabled above.
"Open-collector/open-drain devices sink (flow) current in their low voltage active (logic 0) state, or are high impedance (no current flows) in their high voltage non-active (logic 1) state. These devices usually operate with an external pull-up resistor that holds the signal line high until a device on the wire sinks enough current to pull the line low. Many devices can be attached to the signal wire. If all devices attached to the wire are in their non-active state, the pull-up will hold the wire at a high voltage. If one or more devices are in the active state, the signal wire voltage will be low."
::::The circuit shown is actually a NOR gate, if we use logical "1"=High. Think about it. If the signal to any of the FET's is high (logical "1"), the output is low (logical "0"). Pure NOR. You must edit the page. —Preceding
unsigned comment added by
134.134.136.4 (
talk)
01:36, 7 December 2007 (UTC)reply
[edit] Definition too restrictive
There's no reason to categorize the open-collector or open-drain as an output in only digital design. I've added a plug to that hole in the two articles, but I don't know how to change the categorization or the description immediately following the subject.
Python2k (
talk)
16:52, 19 April 2008 (UTC)reply
combine with open collector?
This could be combined with open-collector and then highlight the difference as a section. This source does a good job of that. Find open-drain towards the end:
Near the beginning of this article is a sentence that states “The word "drain" in the term "Open-drain" refers to the drain terminal of a transistor.” This is a misleading statement as a transistor does not have a “drain.” Instead the sentence should associate “open-drain” with
MOSFET types devices which do have a terminal called drain.
Armstrong1113149 (
talk)
02:20, 13 March 2009 (UTC)reply
This redirect is part of WikiProject Electronics, an attempt to provide a standard approach to writing articles about
electronics on Wikipedia. If you would like to participate, you can choose to edit the redirect attached to this page, or visit the
project page, where you can join the project and see a list of open tasks. Leave messages at the
project talk pageElectronicsWikipedia:WikiProject ElectronicsTemplate:WikiProject Electronicselectronic articles
If you look at the final expression, I think the line over the expression means "active low", or low voltage is 1. (Not exactly - if you're talking about pins on a chip, yes, the overbar means active low. In this case, the overbar means 'not'.
Mystic Pixel) Invert it, makes it active high:
NOT ( (A AND B) OR (C AND D) )
and apply Demorgan's, you get a wired AND:
NOT (A AND B) AND NOT (C AND D)
The gates he is interfaceing are NAND gates, and that fits:
(A NAND B) AND (C NAND D)
So this source says AND even though it labels it OR. (No - he uses NANDs because it's active low.
Mystic Pixel) Well, maybe we need a better source! Here is one:
"They may be connected to other open-drain outputs to implement active-low wired-OR or active-high wired-AND functions."
Hmmm. Somebody else pick it up from here. PLEASE show us your source on this page, no more "because this is correct". If no one can verify it, then well-meaning people will keep "fixing" it.
Dlotts04:06, 20 September 2006 (UTC)reply
A large part of the problem is the mis-application of "logic 1". Logic 1 may be 5V, 12V, 0V, 18V, 3.7V -- the voltage doesn't matter. By saying "logic 1", we just mean "the state that represents the presence of a bit." (That hardwaresecrets page claims '1' means '5V', which is only true in an active-high TTL logic environment.)
Now. About the word "active". "Active low" means that the low voltage state represents Logic 1, while the normal "Active high" method means that the higher of the two voltages represents Logic 1. To be frank, it doesn't mean that much -- it's just a difference in how you interpret the voltage levels.
With that in mind, it's easier to talk about circuits in terms of "enabled" and "disabled" (this is really what '1' and '0' meant, before people started thinking '1' means 'higher voltage' and '0' means 'lower voltage'.) If you think of things this way, 'active-low' circuits are easier to handle, because the only difference is that the 'enabled' state is represented by the lower voltage instead of the higher one.
This brings us to the central point of open-drain (and open-collector) devices. In normal devices, the output is connected to the associated voltage in both the enabled and disabled states. When the output is enabled, it is driven by the +Vcc, and when disabled, it's grounded (switch those for active-low!) However, in OD/OC devices, when the output is disabled, it is not driven by a voltage source or connected to ground! Instead, it presents a high impedance to connected circuitry -- it behaves like it is disconnected, or "open".
If you think about things in these terms, a NAND gate can be thought of as a device that converts active-high to active-low. When both inputs are enabled/higher-voltage, the output is enabled/lower-voltage. Otherwise, the output is disabled (in an open-collector device, this means 'open'.) Make sense? (This might get confusing, because when you're doing a truth table, the output is said to be '1' for the inputs {0,0}, {0,1}, and {1,0}. This indicates the 'higher-voltage' state, which is 'enabled' for active-high logic, but 'disabled' if you're thinking active-low.)
This is why we're using NAND gates to drive the bus, instead of AND gates (and, I think, this is why many busses use an active-low type standard.) Let's do an example.
I build this circuit with regular (not open-drain) devices. For most of the possible input conditions, both NAND gates output higher-voltage ('1', but the bus is active-low, so it's really 'disabled' in those terms.) Since these are regular devices, the output pins are connected to the higher-voltage supply, +Vcc. Now, if A and B both go to 1 (note that the input circuitry is active-high!), then the output of the first NAND goes to '0' -- (but it's active-low, so it's like the output is being 'enabled'). In order to do this, the top NAND connects the output pin to Ground. Now, since the lower gate is still connecting the output to +Vcc, the bus is connected to both ground and Vcc at the same time! The state of the bus is unpredictable at best (worst case, you've shorted your power supply!) Open-drain/Open-collector devices allow us to avoid this.
Now, I rebuild the circuit with open-drain logic gates (note the *), and a pull-up resistor. When the gates are outputting '1', they are 'disabled' (active-low!) and thus, they are 'open' as explained above. As long as nothing is drawing current from the bus, there is no voltage drop across the resistor, and the bus voltage is +Vcc (5V in this case.) The important point is that the gates themselves are not holding the bus at +Vcc. That is being done by the resistor. If I turn on A and B, the first gate 'enables' and goes low, so it is connected to ground. Now, since the bus is shorted to ground, there is 0V on it (all the voltage from the supply goes away, because the current flow creates a voltage drop across the resistor.) This works with open-drain gates because the second gate doesn't try to drive the bus high!
This is (one of) the benefit(s) of open-collector devices. They act as a wired OR in active low logic (using NAND gates, as above.) I just realized the source of the confusion - if you're looking at them from the viewpoint of active high logic, it behaves like a wired AND, since the bus will be '1' only when all the outputs are '1'. While this isn't wrong per se, thinking of it in those terms leads to confusion, because what's really happening is that the bus is being driven low when at least one of the gates connects it to ground.
The article page itself is really confusing, but I can't fix it now. I hope this explanation clears things up. None of my textbooks have a good reference on this, it was something one of my professors explained a few years ago. Here are some other pages I found -- An open-collector BJT behaves the same as an open-drain FET, so the explanations more or less apply to both.
"As there is no pull-up resistor internal to the device an unconnected O/C output will give indeterminate voltage levels if viewed with a CRO or meter. O/C outputs can be connected together to provide greater current sinking ability or as a current driven OR gate."
"[O]pen collector output is simply where a transistor either presents a current path to ground, or not."
This goes back to what I was saying about enabled/disabled above.
"Open-collector/open-drain devices sink (flow) current in their low voltage active (logic 0) state, or are high impedance (no current flows) in their high voltage non-active (logic 1) state. These devices usually operate with an external pull-up resistor that holds the signal line high until a device on the wire sinks enough current to pull the line low. Many devices can be attached to the signal wire. If all devices attached to the wire are in their non-active state, the pull-up will hold the wire at a high voltage. If one or more devices are in the active state, the signal wire voltage will be low."
::::The circuit shown is actually a NOR gate, if we use logical "1"=High. Think about it. If the signal to any of the FET's is high (logical "1"), the output is low (logical "0"). Pure NOR. You must edit the page. —Preceding
unsigned comment added by
134.134.136.4 (
talk)
01:36, 7 December 2007 (UTC)reply
[edit] Definition too restrictive
There's no reason to categorize the open-collector or open-drain as an output in only digital design. I've added a plug to that hole in the two articles, but I don't know how to change the categorization or the description immediately following the subject.
Python2k (
talk)
16:52, 19 April 2008 (UTC)reply
combine with open collector?
This could be combined with open-collector and then highlight the difference as a section. This source does a good job of that. Find open-drain towards the end:
Near the beginning of this article is a sentence that states “The word "drain" in the term "Open-drain" refers to the drain terminal of a transistor.” This is a misleading statement as a transistor does not have a “drain.” Instead the sentence should associate “open-drain” with
MOSFET types devices which do have a terminal called drain.
Armstrong1113149 (
talk)
02:20, 13 March 2009 (UTC)reply