Keysight Labs | How to Make Third Order Intercept (TOI) Measurements @KeysightLabs | Uploaded July 2018 | Updated October 2024, 2 hours ago.
Learn how to characterize weak nonlinear systems and devices.
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The signal generator we used: bit.ly/XSeriesSignalGenerators
(The Keysight X-Series MXG 9 kHz - 6 GHz)
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Transcript:
When two or more signals are modulated, they produce a form of distortion called intermodulation products. These intermodulation products are distortion that results from nonlinearities in a system. Intermodulation products can prove to be quite problematic because of their close proximity to fundamental frequencies. Today, we’ll discuss how you can characterize your device’s third order intercept value so that you can measure for weak device components and model your system’s nonlinearity.
Hi, I’m Ally, and welcome to Keysight’s Rapid Measurement Series. In this video, we’ll be exploring the third order intercept or TOI.
The problem is that intermodulation products tend to be in the same band as our fundamental frequencies, so we can’t just filter them out.
By intermodulation products we mean that if you have a device that is transmitting a modulated signal, it will create additional signals at frequencies that are not just harmonics. It also creates the sum and difference of the original frequencies.
Another issue we need to be wary of is the fact that intermodulation products’ power levels increase by a factor of three, relative to an increase in the power level of the fundamental tones.
TOI is useful for characterizing weak nonlinear systems and devices such as amplifiers.
The TOI measures your device’s linearity.
To find the TOI, you have to plot out two things- the output power of your fundamental and the output power of your intermodulation products over varying input powers.
It should look something like this.
The third order intercept point, is the extrapolated intersection point of the fundamental power curve and the intermodulation power curve. We can’t measure it directly because our amplifiers aren’t designed for that level of input power, but you can find it mathematically by extrapolating the two curves.
At this point, the power of the fundamental is the same as the power of the intermodulation products.
A high TOI value means your system has good linearity. A low TOI value means your intermodulation products could interfere with your fundamental signal.
The specific TOI requirements depend on the technologies you are working with.
TOI can be measured manually by sweeping through input powers and measuring the fundamental and intermodulation powers. Or some signal analyzers can do it automatically- kind of like a bode plot.
Using this signal analyzer, we are measuring a two-tone modulated signal. We can automatically compute the third order intercept of these signals and place markers on the trace to indicate the measured signals and their third order products.
Here we’ve calculated the third order intercept of a two-tone signal. The TOI measurement begins by taking a sweep of the incoming signal, then it measures the two fundamental tones, and finally measures the third order intermodulation products.
With this measurement table we can also see the absolute power of each fundamental tone, the absolute and relative power for both the upper and lower intermodulation products, and the power of the third order intercept.
This information helps us accurately measure intermodulation and determine how linear our system is. Having a signal analyzer with good dynamic range also gives us the ability to measure the TOI point we are looking for. The better the dynamic range, the improved ability our signal analyzer has to measure harmonically related signals and intermodulation products needed to be able to characterize the system under test.
Learn how to characterize weak nonlinear systems and devices.
1-Click Subscribe: bit.ly/Labs_Sub
Download "Making Fast and Accurate Power Measurements:" bit.ly/2GQ4Qu0
Like our Facebook page: facebook.com/keysightrf
Check out our blog: bit.ly/RFTestBlog
Check out the EEs Talk Tech electrical engineering podcast:
eestalktech.com
The signal analyzer we used: bit.ly/XSeriesSignalAnalyzers
(The Keysight X-Series MXA 10 Hz - 26.5 GHz)
The signal generator we used: bit.ly/XSeriesSignalGenerators
(The Keysight X-Series MXG 9 kHz - 6 GHz)
Twitter: @DanielBogdanoff twitter.com/DanielBogdanoff
Transcript:
When two or more signals are modulated, they produce a form of distortion called intermodulation products. These intermodulation products are distortion that results from nonlinearities in a system. Intermodulation products can prove to be quite problematic because of their close proximity to fundamental frequencies. Today, we’ll discuss how you can characterize your device’s third order intercept value so that you can measure for weak device components and model your system’s nonlinearity.
Hi, I’m Ally, and welcome to Keysight’s Rapid Measurement Series. In this video, we’ll be exploring the third order intercept or TOI.
The problem is that intermodulation products tend to be in the same band as our fundamental frequencies, so we can’t just filter them out.
By intermodulation products we mean that if you have a device that is transmitting a modulated signal, it will create additional signals at frequencies that are not just harmonics. It also creates the sum and difference of the original frequencies.
Another issue we need to be wary of is the fact that intermodulation products’ power levels increase by a factor of three, relative to an increase in the power level of the fundamental tones.
TOI is useful for characterizing weak nonlinear systems and devices such as amplifiers.
The TOI measures your device’s linearity.
To find the TOI, you have to plot out two things- the output power of your fundamental and the output power of your intermodulation products over varying input powers.
It should look something like this.
The third order intercept point, is the extrapolated intersection point of the fundamental power curve and the intermodulation power curve. We can’t measure it directly because our amplifiers aren’t designed for that level of input power, but you can find it mathematically by extrapolating the two curves.
At this point, the power of the fundamental is the same as the power of the intermodulation products.
A high TOI value means your system has good linearity. A low TOI value means your intermodulation products could interfere with your fundamental signal.
The specific TOI requirements depend on the technologies you are working with.
TOI can be measured manually by sweeping through input powers and measuring the fundamental and intermodulation powers. Or some signal analyzers can do it automatically- kind of like a bode plot.
Using this signal analyzer, we are measuring a two-tone modulated signal. We can automatically compute the third order intercept of these signals and place markers on the trace to indicate the measured signals and their third order products.
Here we’ve calculated the third order intercept of a two-tone signal. The TOI measurement begins by taking a sweep of the incoming signal, then it measures the two fundamental tones, and finally measures the third order intermodulation products.
With this measurement table we can also see the absolute power of each fundamental tone, the absolute and relative power for both the upper and lower intermodulation products, and the power of the third order intercept.
This information helps us accurately measure intermodulation and determine how linear our system is. Having a signal analyzer with good dynamic range also gives us the ability to measure the TOI point we are looking for. The better the dynamic range, the improved ability our signal analyzer has to measure harmonically related signals and intermodulation products needed to be able to characterize the system under test.
![9 Bench Power Supply Tips You Need to Know [Tutorial]](https://i.ytimg.com/vi/cmduKuMLDsc/hqdefault.jpg "9 Bench Power Supply Tips You Need to Know [Tutorial]
Become a bench power supply master!
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The power supply tips in order:
00:00 Introduction and where have we been?
1:30 What is Power Supply Load Regulation
2:15 What is Power Supply Transient Response
3:00 What is Power Supply Line Regulation
4:04 What is Power Supply Programming Accuracy
4:34 What is Power Supply Readback Accuracy
5:47 What is Power Supply Resolution
6:18 What is Power Supply Output Noise
7:16 What are Power Supply Remote Sense Connections
8:30 Power Supply Interfaces and Remote Control
10:32 Power Supply Protection Capabilities
11:32 What are Power Supply Fault Triggers
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Bench power supplies can be basic, and they can be complex. This tutorial video covers essential, basic bench power supply tips that all electrical engineers should know. They are crucial for electronics work, lab work, electrical design work, and can blow up your devices if they arent used properly.
This video explores 9 tips and capabilities you should look for in your bench power supply.
Load regulation — the variability in the output V/I due to change in load. Some loads will not tolerate voltage variations greater than a few percent
Line regulation — the variability in the output V/I due to change in AC input
Programming accuracy — the quality of the programmed value being near to the actual V/I
Read back accuracy — the quality of the displayed value being near to the actual V/I
Resolution — the smallest value of V/I that can be programmed
Output noise — consists of common mode and normal mode
Transient response — time taken for the output voltage to return to the programmed state after a disruptive change in load current
Sense connections — local and/or remote sense capability
Interface — front panel and/or remote (LAN, GPIB, USB, RS232, etc.)
Low noise, excellent regulation, and remote sensing capability that reduces the voltage drop across load leads, are the desired characteristics in a power supply.
When dealing with power, safety comes first. Sometimes when devices fail, it may be catastrophic. It is important that a power supply not only protect itself, but also protect the DUT. Protection circuits in the power supply can limit the voltage or current to a preset level or shut down the power supply when an overvoltage or overcurrent condition occurs. Some power supplies also have a down programmer circuit to quickly discharge the DUT while some, upon receiving a fault trigger, are able to open a relay and isolate the DUT from the source of the power.
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