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Transcript
Topic 1.1.3 – Simple digital outputs Learning Objectives: At the end of this topic you will be able to; Recall the use of an LED and resistor to indicate the output state of a logic system; Understand that a logic gate output can be configured to either source or sink current. 1 Module ET1 Introduction to Analogue and Digital Systems. Simple Output Devices. In topic 1.1.2 we examined how signals are processed for entry into a logic system. In this unit we will be concerned with the output stage of the logic system, since if we do not know when the output of a system is switched on, there is no point in designing the system in the first place. The output current from a standard logic gate is quite small (20mA) and this is far too small to operate the majority of output devices like motors, solenoids, relays and lamps. In order to operate these devices we need an extra interface unit which is not covered until ET2, therefore none of these devices will be discussed for the rest of this unit, nor will they be asked for in the ET1 examination. The only output device that we will consider is the Light Emitting Diode or LED for short. This is a component that comes in various shapes, sizes and colours as shown below: 2 Topic 1.1.3 – Simple digital outputs The circuit symbol for an LED irrespective of its colour or shape is : The LED gives off light when a small current 10mA flows through it. This makes it perfectly suitable for use with logic gates as an output device. The LED is normally used in the following way. OR Gate Output 0 1 Status of LED Off On The resistor is included to provide some protection to the LED and will be discussed in more detail in ET2. You will not be asked to perform any calculations involving this resistor in ET1 questions. Now when the output of the OR gate shown above is at Logic 0, (0V) there is no difference in voltage between the output of the logic gate and the 0V line, so the LED will be off. However when the output of the OR gate reaches Logic 1 (High Voltage) then there will be a difference in voltage between the output of the logic gate and the 0V line, a current will therefore flow through the resistor and LED, light will be produced indicating that the output is on. Note: Any gate could have been used to drive the LED. In this case we say that the output of the logic gate is ‘sourcing’ current, i.e. current is flowing out of the logic gate into the resistor and LED, and then down to the 0V line of the power supply. There is another way in which we can use the LED to provide the opposite function to that described above. This is less common but could appear on the examination paper as an alternative circuit application. 3 Module ET1 Introduction to Analogue and Digital Systems. Study the following circuit carefully: OR Gate Output 0 1 Status of LED On Off In this circuit the LED has been connected to the +9V supply. Let us consider the two possible output conditions of the OR gate once again and see the effect on the LED. When the output of the OR gate is at Logic 0 (0V), there is a difference in voltage between the power supply and the output of the logic gate, current therefore flows through the resistor and LED and it lights up. When the output of the logic gate is Logic 1 (9V) there is no difference in voltage between the power supply and the output of the logic gate, therefore no current will flow and the LED will be off. Note: Any gate could have been used to drive the LED. In this case we say that the output of the logic gate is ‘sinking’ current, i.e. current is flowing into the logic gate from the power supply and through the LED. In many circuits that you will come across in the following chapters the output device. i.e. the LED will be represented by a circle at the end of the logic system to save complicating a logic diagram with resistors and LED symbols, but this is just to save time. In any practical circuit you construct, you will have to add the resistor and LED to your output to be able to see when it is on. So now we have the basics – lets start designing ! Next stop topic 1.2 4 Topic 1.1.3 – Simple digital outputs Self Evaluation Review Learning Objectives My personal review of these objectives: Recall the use of an LED and resistor to indicate the output state of a logic system; Understand that a logic gate output can be configured to either source or sink current. Targets: 1. ……………………………………………………………………………………………………………… ……………………………………………………………………………………………………………… 2. ……………………………………………………………………………………………………………… ……………………………………………………………………………………………………………… 5
