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| university:courses:electronics:labs [05 Aug 2014 02:48] – add comms lab Doug Mercer | university:courses:electronics:labs [01 Nov 2021 18:20] (current) – Add Wien Bridge Oscillator, Standing Waves Mark Thoren |
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| ====== Lab Activity Material Outline, Electronics I and II ====== | ====== ADALM2000 Based Lab Activity Material, Electronics I and II ====== |
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| Analog Devices is as passionate about educating the next generation of young circuit design engineers as it is about pioneering the next technological breakthrough. The University Program is a platform where Analog Devices, working with leading educational institutions has created and deployed new hands on learning tools for the next generation of analog circuit design engineers. The University Program brings the analog signal processing technology the company has developed to the academic community in a way that is open and accessible to faculty and students in the form of analog design kits and analog components, online and downloadable software and teaching materials, online support, textbooks, reference designs and lab projects to enrich students’ education about analog circuits and their application to core engineering and physical science curricula. | Analog Devices is as passionate about educating the next generation of young circuit design engineers as it is about pioneering the next technological breakthrough. The University Program is a platform where Analog Devices, working with leading educational institutions has created and deployed new hands on learning tools for the next generation of analog circuit design engineers. The University Program brings the analog signal processing technology the company has developed to the academic community in a way that is open and accessible to faculty and students in the form of analog design kits and analog components, online and downloadable software and teaching materials, online support, textbooks, reference designs and lab projects to enrich students’ education about analog circuits and their application to core engineering and physical science curricula. |
| The laboratory activities provided on this wiki are considered open source and available for free use in non-commercial educational and academic settings. **The only requirement is that they continue to retain the attribution to Analog Devices Inc.** Supplying them on the ADI wiki allows registered users to contribute to the materials posted here improving the content and keeping them up to date. | The laboratory activities provided on this wiki are considered open source and available for free use in non-commercial educational and academic settings. **The only requirement is that they continue to retain the attribution to Analog Devices Inc.** Supplying them on the ADI wiki allows registered users to contribute to the materials posted here improving the content and keeping them up to date. |
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| In general these labs can be performed with just the components provided in the Analog Parts Kits supplied by [[http://www.digilentinc.com/Products/Detail.cfm?NavPath=2,842,845&Prod=APK|Digilent]] however additional devices are sometimes needed. Other sources of components can of course be used and there is additional information on that further down on this page. | In general these labs can be performed using the [[university:tools:m2k|ADALM2000]] (M2K) Active Learning Module and [[university:tools:m2k:scopy|Scopy]] software. It is also possible to perform these lab activities using the ADALM1000 (M1K) hardware module with minor adjustments to the circuits. [[university:courses:alm1k:m2k-convert-labs|This document]] outlines how the labs might be altered for use with M1K and the ALICE desktop software. |
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| **Pre-Lab Circuit Simulation** | They are generally written to be performed with just the components provided in the [[university:tools:adalp2000:parts-index|ADALP2000]] Analog Parts Kit, however additional devices are sometimes needed. Other sources of components can of course be used and there is additional information on that further down on this page. If you are looking for Lab Activity material written specifically for use with the [[university:courses:alm1k:alm-labs-list|ADALM1000 look here]]. |
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| | Most of the labs are populated with [[adi>en/design-center/design-tools-and-calculators/ltspice-simulator.html | LTSpice]] resource files which contain the schematics of the circuits discussed at a specific topic. An file containing the ADALM2000 connections for the schematics can be found here: [[downgit>education_tools/tree/master/m2k/ltspice/m2k_conn_ltspice | m2k_conn_ltspice]]. |
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| | ====Pre-Lab Circuit Simulation==== |
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| Notes on [[university:courses:electronics:circuitsimulationnotes|circuit simulation]].\\ | Notes on [[university:courses:electronics:circuitsimulationnotes|circuit simulation]].\\ |
| Links to an archive of example simulation schematic files are provided below. | Links to an archive of example simulation schematic files are provided below. |
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| **General Lab materials** | ====General Lab materials==== |
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| - Background Lab Notes: [[university:courses:electronics:electronics-lab-breadboards|Solder-less Breadboards]] | - Background Lab Notes: [[university:courses:electronics:electronics-lab-breadboards|Solder-less Breadboards]] |
| - Basic Activity: [[university:courses:electronics:electronics-lab-eh|Energy Harvesting]] | - Basic Activity: [[university:courses:electronics:electronics-lab-eh|Energy Harvesting]] |
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| **Electronics I** | ====Electronics I==== |
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| Electronics I pre-lab simulation {{:university:courses:electronics:electronics-lab-i.zip|schematic files}}. | Electronics I pre-lab simulation [[downgit>education_tools/tree/master/m2k/adisimpe/electronics-lab-i|schematic files]]. |
| | - [[university:courses:electronics:ohm_law|An Ohm's Law Experiment]] |
| - [[university:courses:electronics:electronics-lab-1|Basic OP Amp Configurations]], [[university:courses:electronics:electronics-lab-1st|Op Amp Settling Time]] | - [[university:courses:electronics:rc_transient_response|Transient Response of an RC Circuit]] |
| | - [[university:courses:electronics:rl_transient_response|Transient Response of an RL Circuit]] |
| | - [[university:courses:electronics:lp_hp_filters|Low Pass and High Pass Filters]] |
| | - [[university:labs:band_pass_filters_adalm200|Band Pass Filters]] |
| | - [[university:labs:band_stop_filters_adalm2000|Band Stop Filters]] |
| | - [[university:courses:electronics:rlc_resonance|Resonance in RLC Circuits]] |
| | - [[university:labs:cascaded_rc_adalm2000|Cascaded RC low pass filters]] |
| | - [[university:courses:electronics:electronics-lab-1|Simple Op Amps]],[[university:courses:electronics:electronics-lab-opamp-comparator|Op Amp as Comparator]],[[university:courses:electronics:electronics-lab-1st|Op Amp Settling Time]], [[university:courses:electronics:electronics-lab-loop-gain|Measuring Loop Gain]] |
| - [[university:courses:electronics:electronics-lab-2|PN Diode I/V curves]] | - [[university:courses:electronics:electronics-lab-2|PN Diode I/V curves]] |
| - [[university:courses:electronics:electronics-lab-pn-junction-cap|Voltage dependent capacitance of the PN junction]] | - [[university:courses:electronics:electronics-lab-pn-junction-cap|Voltage dependent capacitance of the PN junction]] |
| - [[university:courses:electronics:electronics-lab-3|BJT as a diode]], [[university:courses:electronics:electronics-lab-3m|MOS as a diode]] | - [[university:courses:electronics:electronics-lab-3|BJT as a diode]], [[university:courses:electronics:electronics-lab-3m|MOS as a diode]] |
| - Device I/V curves, [[university:courses:electronics:electronics-lab-4|BJT]] and [[university:courses:electronics:electronics-lab-4m|MOS]] | - Device I/V curves, [[university:courses:electronics:electronics-lab-4|BJT]] and [[university:courses:electronics:electronics-lab-4m|MOS]] |
| - [[university:courses:electronics:electronics-lab-5|Common emitter amplifier]], [[university:courses:electronics:electronics-lab-5m|Common source amplifier]], [[university:courses:electronics:electronics-lab-5fr|Amplifier Frequency Response]] | - [[university:courses:electronics:electronics-lab-5|Common emitter amplifier]], [[university:courses:electronics:electronics-lab-5m|Common source amplifier]], [[university:courses:electronics:electronics-lab-5fr|Amplifier Frequency Response]], [[university:courses:electronics:electronics-lab-ce-loop-gain|CE amplifier loop gain]] |
| - [[university:courses:electronics:electronics-lab-6|BJT Current Mirror]], [[university:courses:electronics:electronics-lab-6m|MOS Current Mirror]] | - [[university:courses:electronics:electronics-lab-6|BJT Current Mirror]], [[university:courses:electronics:electronics-lab-6m|MOS Current Mirror]] |
| - [[university:courses:electronics:electronics-lab-7|BJT Zero gain amplifier]], [[university:courses:electronics:electronics-lab-7m|MOS Zero gain amplifier]] | - [[university:courses:electronics:electronics-lab-7|BJT Zero gain amplifier]], [[university:courses:electronics:electronics-lab-7m|MOS Zero gain amplifier]] |
| - [[university:courses:electronics:electronics-lab-13|Making a full Amplifier from circuit blocks]]. [[university:courses:electronics:electronics-lab-13a|Output Stages]] | - [[university:courses:electronics:electronics-lab-13|Making a full Amplifier from circuit blocks]]. [[university:courses:electronics:electronics-lab-13a|Output Stages]] |
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| **Electronics II** | ====Electronics II==== |
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| Electronics II pre-lab simulation {{:university:courses:electronics:electroincs-lab-ii.zip|schematic files}}. | Electronics II pre-lab simulation [[downgit>education_tools/tree/master/m2k/adisimpe/electronics-lab-ii|schematic files]]. |
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| - [[university:courses:electronics:electronics-lab-20|CMOS Amplifier]] (with chopping / auto zero) | - [[university:courses:electronics:electronics-lab-20|CMOS Amplifier]] (with chopping / auto zero) |
| - [[university:courses:electronics:electronics-lab-18|CMOS Analog Switches]] | - [[university:courses:electronics:electronics-lab-18|CMOS Analog Switches]] |
| - [[university:courses:electronics:electronics-lab-19|Switched Capacitor circuits]] | - [[university:courses:electronics:electronics-lab-19|Switched Capacitor circuits]] |
| - Analog to Digital and [[university:courses:electronics:electronics-lab-14|Digital to Analog]] Conversion | - [[university:courses:electronics:electronics-lab-adc|Analog to Digital]] and [[university:courses:electronics:electronics-lab-14|Digital to Analog]] Conversion |
| - [[university:courses:electronics:electronics-lab-17|Delta – Sigma Modulator]] | - [[university:courses:electronics:electronics-lab-17|Delta – Sigma Modulator]] |
| - [[university:courses:electronics:electronics-lab-21|CMOS LC Oscillator]] | - [[university:courses:electronics:electronics-lab-21|CMOS LC Oscillator]] |
| - [[university:courses:electronics:electronics-lab-30|CMOS Logic Circuits, Transmission Gate XOR]] | - [[university:courses:electronics:electronics-lab-30|CMOS Logic Circuits, Transmission Gate XOR]] |
| - [[university:courses:electronics:electronics-lab-29|CMOS Logic Circuits, D Type Latch]] | - [[university:courses:electronics:electronics-lab-29|CMOS Logic Circuits, D Type Latch]] |
| | - [[university:courses:electronics:electronics-lab-voltage-level-shifter|Logic Voltage Level Shifting]] |
| - [[university:courses:electronics:electronics-lab-31|Phase locked loops]] | - [[university:courses:electronics:electronics-lab-31|Phase locked loops]] |
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| **Miscellaneous Lab Activities ** | ====Miscellaneous Lab Activities==== |
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| - [[university:courses:electronics:electronics-lab-led-sensor|LED as light sensor]] | - [[university:courses:electronics:electronics-lab-led-sensor|LED as light sensor]] |
| | - [[university:courses:eps:photovoltaic|Characteristics of Photovoltaic Solar Cells]] |
| - [[university:courses:electronics:electronics-lab-nr|Negative voltage reference from positive reference]] | - [[university:courses:electronics:electronics-lab-nr|Negative voltage reference from positive reference]] |
| - [[university:courses:electronics:electronics-lab-speaker|Measuring a Loudspeaker Impedance Profile]] | - [[university:courses:electronics:electronics-lab-speaker|Measuring a Loudspeaker Impedance Profile]] |
| - [[university:courses:electronics:electronics-lab-external-trigger|Adjustable External Triggering Circuit]] | - [[university:courses:electronics:electronics-lab-external-trigger|Adjustable External Triggering Circuit]] |
| | - [[university:courses:electronics:electronics-lab-heartbeat|Heartbeat Measurement Circuit]] |
| | - [[university:courses:electronics:electronics-lab-window-comp-tmp01|Temperature Control using Window Comparator]] |
| | - [[university:courses:electronics:magnetic_proximity_sensor|Magnetic proximity sensor]] |
| | - [[university:labs:2_axis_tilt_sensor_adalm2000|2-Axis Tilt Sensor]] |
| | - [[university:courses:electronics:temperature_measuring|IC temperature sensors]] |
| | - [[university:courses:electronics:electronics-lab-electret_microphone|Audio Amplifier with Electret Microphone]] |
| | ====Communications Circuits==== |
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| ** Communications Circuits ** | - [[university:labs:comms_lab_isr_adalm2000|Inductor Self Resonance]] |
| | - [[university:labs:comms_lab_transformers_adalm2000|Transformers]] |
| - [[university:courses:electronics:comms-lab-isr|Inductor Self Resonance]] | - [[university:labs:comms_lab_tuned_amplifiers_1_adalm2000|Tuned Amplifiers,part I]], [[university:labs:comms_lab_tuned_amplifiers_2_adalm2000|Tuned Amplifiers,part II]] |
| - Transformers | - [[university:labs:electronics_lab_transformer_coupled_amp_adalm2000|Transformer Coupled Amplifier]] |
| - Tuned Amplifiers | - [[university:courses:electronics:electronics-lab-active-filter|Active Filters]], [[university:courses:electronics:comms-lab-polyphase-filter|Polyphase Filters]] |
| - Active Filters | - [[university:courses:electronics:electronics-lab-envelope-detector|Envelope Detectors]] |
| - Envelop Detectors | - [[university:courses:electronics:electronics_lab_fm_detectors|FM Detectors]] |
| - FM Detectors | - [[university:courses:electronics:electronics-lab-variable-gain-amplifier|Variable Gain Amplifiers]] |
| - Variable Gain Amplifiers | - [[university:courses:electronics:electronics-lab-pulse-width-modulation|Pulse Width Modulation]] |
| - Pulse Width Modulation | - Frequency Synthesizers, [[university:courses:electronics:comms-lab-hartley-osc|Hartley oscillator]], [[university:courses:electronics:comms-lab-colpitts-osc|Colpitts oscillator]], [[university:courses:electronics:comms-lab-clapp-osc|Clapp oscillator]], [[university:courses:electronics:comms-lab-peltz-osc|Peltz Oscillator]] |
| - Frequency Synthesizers | - [[university:labs:wien_bridge_osc_adalm2000|The Wien Bridge Oscillator]] |
| - Phase Locked Loops | - [[university:courses:electronics:comms-lab-pulse-osc|Pulsed Oscillators]] |
| - Diode Ring Modulators | - [[university:courses:electronics:electronics_lab_diode_ring_modulator|Diode Ring Modulators]] |
| - Active Mixers | - [[university:courses:electronics:electronics-lab-active-mixer|Active Mixers]] |
| - [[university:courses:electronics:comms-lab-lfsr|Pseudo-Random Sequence Generators]] | - [[university:courses:electronics:comms-lab-lfsr|Pseudo-Random Sequence Generators]] |
| ===== General background Information. ===== | - [[university:labs:tlines_standing_waves_adalm2000|Transmission Lines and Standing Waves]] |
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| | ====Power Management Circuits==== |
| | - [[university:courses:electronics:switched-cap-power-supplies|Switched Capacitor Power Supplies]] |
| | - [[university:courses:electronics:buck_converter_basics|Buck Converter Basics]] |
| | - [[university:courses:electronics:efficiency_power_loss|Efficiency, Power Loss, and Thermal Management]] |
| | - [[university:labs:open_loop_boost_and_buck_adalm2000|Boost and Buck converter elements and open-loop operation]] |
| | - [[university:labs:closed_loop_buck_adalm2000|Buck Converters: closed loop operation]] |
| | - [[university:labs:closed_loop_boost_adalm2000|Boost Converters: closed loop operation]] |
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| | ====Tutorials==== |
| | - [[university:courses:electronics:tutorials|ADALM2000 Tutorials]] //(temporary link)// |
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| | ====== General background Information. ====== |
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| The assumption is made that the reader has some familiarity with the Analog Discovery Lab hardware and Waveforms software system before starting these lab activities. It is also assumed that for the data presented here, the measurement data waveforms from the lab hardware were saved to disk and manipulated and plotted in Microsoft Excel. | The assumption is made that the reader has some familiarity with the ADALM2000 Lab hardware and Scopy software system before starting these lab activities. It is also assumed that for the data presented here, the measurement data waveforms from the lab hardware were saved to disk and manipulated and plotted in Microsoft Excel. |
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| First, here are a few words about components that might be suitable for use in these lab experiments. Transistors that can be used are general purpose NPN types like 2SC1815 and the 2SA1015 PNP complement. Similar type devices can be used such as the popular 2N3904 NPN and 2N3906 PNP devices which are also considered comparable complements of each other. A supply of various diodes, resistors, capacitors and inductors should also be available. Another potential source of transistors for use in these lab exercises are transistor arrays such as the LM3045 / LM3046 / LM3086 NPN Arrays from National Semiconductor. Similar NPN arrays from Intersil are, CA3045 / CA3046 / CA3083. Arrays of two or four 2N2222, 2N3904, 2N3906 and other types are available from some manufacturers like Fairchild and ON Semiconductor. A readily available enhancement mode NMOS transistor is the 2N7000. Advanced Linear Devices Inc. offers dual and quad N and P channel MOS arrays (ALD1106 and ALD1107) as well. The CD4007C CMOS logic package consists of three complementary pairs of N and P-channel enhancement mode MOS transistors. The N and P type pairs share either a common gate or common drain terminal which limits their use as six individual devices but these devices can still be useful for Lab experiments. | First, here are a few words about components that might be suitable for use in these lab experiments. Transistors that can be used are general purpose NPN types like 2SC1815 and the 2SA1015 PNP complement. Similar type devices can be used such as the popular 2N3904 NPN and 2N3906 PNP devices which are also considered comparable complements of each other. A supply of various diodes, resistors, capacitors and inductors should also be available. Another potential source of transistors for use in these lab exercises are transistor arrays such as the LM3045 / LM3046 / LM3086 NPN Arrays from National Semiconductor. Similar NPN arrays from Intersil are, CA3045 / CA3046 / CA3083. Arrays of two or four 2N2222, 2N3904, 2N3906 and other types are available from some manufacturers like Fairchild and ON Semiconductor. A readily available enhancement mode NMOS transistor is the 2N7000. Advanced Linear Devices Inc. offers dual and quad N and P channel MOS arrays (ALD1106 and ALD1107) as well. The CD4007C CMOS logic package consists of three complementary pairs of N and P-channel enhancement mode MOS transistors. The N and P type pairs share either a common gate or common drain terminal which limits their use as six individual devices but these devices can still be useful for Lab experiments. |
| Remember, not all transistors share the same terminal designations, or pinouts, even if they share the same physical appearance. The order of some types is CBE (base is center lead) and BCE (collector is center lead) for others. This is very important when you connect the transistors together and to other components. Be careful to check the manufacturer's specifications (component datasheet). These can be easily found on various websites. Double-checking pin identities with a multi-meter's "diode check" function is highly recommended. | Remember, not all transistors share the same terminal designations, or pinouts, even if they share the same physical appearance. The order of some types is CBE (base is center lead) and BCE (collector is center lead) for others. This is very important when you connect the transistors together and to other components. Be careful to check the manufacturer's specifications (component datasheet). These can be easily found on various websites. Double-checking pin identities with a multi-meter's "diode check" function is highly recommended. |
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| ===== Extra stuff: ===== | ====== Extra stuff: ====== |
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| Learning to mathematically analyze circuits requires much study and practice. Typically, students practice by working through lots of sample problems and checking their answers against those provided by the textbook or the instructor. While this is good, there is a much better way. You will learn much more by actually building and analyzing real circuits, letting your test equipment provide the "answers" instead of a book or another person. For successful circuit-building exercises, follow these steps: | Learning to mathematically analyze circuits requires much study and practice. Typically, students practice by working through lots of sample problems and checking their answers against those provided by the textbook or the instructor. While this is good, there is a much better way. You will learn much more by actually building and analyzing real circuits, letting your test equipment provide the "answers" instead of a book or another person. For successful circuit-building exercises, follow these steps: |
| One way you can save time and reduce the possibility of error is to begin with a very simple circuit and incrementally add components to increase its complexity after each analysis, rather than building a whole new circuit for each practice activity. Another time-saving technique is to re-use the same components in a variety of different circuit configurations. This way, you won't have to measure any component's value more than once. | One way you can save time and reduce the possibility of error is to begin with a very simple circuit and incrementally add components to increase its complexity after each analysis, rather than building a whole new circuit for each practice activity. Another time-saving technique is to re-use the same components in a variety of different circuit configurations. This way, you won't have to measure any component's value more than once. |
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| ==== Note about diodes and bandgap conventions: ==== | ====== Note about diodes and bandgap conventions: ====== |
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| The common convention is that a typical silicon BJT base–emitter diode drop, ''V<sub>BE</sub>'', is 0.65V and a standard general purpose silicon diode drop is 0.6V. Other conventions use 0.6V or 0.7V for one or both. These are highly dependent on the manufacturing process used and the physical size of the components. The results you measure in the laboratory will most likely be between these values. Diodes and BJTs implemented on the same integrated circuit (i.e., on the same silicon die) may have equivalent characteristics. That is, the diodes and transistors will be more closely matched. Matched components are convenient to use in many circuit designs. We use discrete elements in most of these activities, and so it is not possible to match components unless they are all fabricated on the same silicon die. In the laboratory, a diode-connected transistor, with its base shorted to its collector may match the base–emitter characteristics of another transistor of the same type better than a simple diode. | The common convention is that a typical silicon BJT base–emitter diode drop, ''V<sub>BE</sub>'', is 0.65V and a standard general purpose silicon diode drop is 0.6V. Other conventions use 0.6V or 0.7V for one or both. These are highly dependent on the manufacturing process used and the physical size of the components. The results you measure in the laboratory will most likely be between these values. Diodes and BJTs implemented on the same integrated circuit (i.e., on the same silicon die) may have equivalent characteristics. That is, the diodes and transistors will be more closely matched. Matched components are convenient to use in many circuit designs. We use discrete elements in most of these activities, and so it is not possible to match components unless they are all fabricated on the same silicon die. In the laboratory, a diode-connected transistor, with its base shorted to its collector may match the base–emitter characteristics of another transistor of the same type better than a simple diode. |
