Qual é o objetivo deste tutorial?

O objetivo é ensinar o design de amplificadores de potência, desde um dispositivo simples até um layout finalizado, incluindo validações para sinais modulados.

Quantas partes tem o tutorial?

O tutorial é dividido em três partes.

O que será abordado na segunda parte?

Na segunda parte, será abordado o design da rede de correspondência e a otimização do amplificador.

Por que a eficiência é importante em amplificadores de potência?

A eficiência é crucial para reduzir custos operacionais e prolongar a vida útil da bateria em dispositivos portáteis.

Quais classes de operação de amplificadores são discutidas?

As classes A, B, AB e C são discutidas, cada uma com suas vantagens e desvantagens.

Qual dispositivo é utilizado como exemplo no tutorial?

Um dispositivo de nitreto de gálio (GaN) da Cree, o CGH 410, é utilizado como exemplo.

Por que os dispositivos GaN são populares?

Os dispositivos GaN têm maior densidade de potência e eficiência em comparação com outras tecnologias.

O que é análise de carga?

A análise de carga é um processo para determinar a impedância ideal para maximizar a eficiência e a potência de saída do amplificador.

Qual é a importância de um modelo não linear?

Um modelo não linear adequado é essencial para prever o desempenho do amplificador durante a simulação.

DPD significa pré-distorção digital, uma técnica usada para melhorar a linearidade do amplificador.

RF Design-16: Practical Power Amplifier Design - Part 1

00:52:28

https://www.youtube.com/watch?v=-GLPH9BYvSo

الملخص

TLDREste vídeo é a primeira parte de um tutorial em três partes sobre o design prático de amplificadores de potência. O objetivo é levar os espectadores desde um dispositivo simples até um layout finalizado de amplificador de potência, validado para análises de sinal modulado e digital. O vídeo cobre tópicos como a importância da carga e fonte, análise de eficiência e linearidade, e a necessidade de um modelo não linear adequado. O apresentador também discute diferentes classes de operação de amplificadores e a importância de dispositivos de nitreto de gálio (GaN) para designs de amplificadores de potência.

الوجبات الجاهزة

🔧 Tutorial em três partes sobre design de amplificadores de potência.
📈 Importância da eficiência e linearidade em amplificadores.
⚙️ Dispositivos GaN são preferidos por sua alta densidade de potência.
📊 Análise de carga é crucial para otimização do amplificador.
📚 Modelos não lineares são essenciais para previsões precisas.
🔍 Diferentes classes de operação têm suas vantagens e desvantagens.
💡 DPD melhora a linearidade do amplificador.
📅 Segunda parte abordará design de rede de correspondência.
📉 A eficiência impacta custos operacionais e duração da bateria.
🛠️ O design começa com um bom modelo não linear.

الجدول الزمني

00:00:00 - 00:05:00
Benvido ao tutorial 16 sobre o deseño práctico de amplificadores de potencia. Este é o primeiro de tres vídeos que cubrirán desde un dispositivo simple ata un deseño finalizado de amplificador de potencia validado para diferentes análises de sinais.
00:05:00 - 00:10:00
O obxectivo desta serie de tutoriales é guiar aos espectadores a través do proceso de deseño de amplificadores de potencia, incluíndo a análise de sinais modulados e a predistorción dixital para obter as especificacións adecuadas para comunicacións sen fíos.
00:10:00 - 00:15:00
Os amplificadores de potencia son fundamentais na cadea de transmisión de calquera sistema sen fíos, xa que deben producir suficiente potencia de saída para superar as perdas do canal entre o transmisor e o receptor, garantindo a mellor calidade de enlace posible.
00:15:00 - 00:20:00
A eficiencia é un dos principais requisitos no deseño de amplificadores de potencia, xa que afecta directamente aos custos operativos e á duración da batería en dispositivos portátiles. A linealidade tamén é crucial para preservar a integridade da sinal.
00:20:00 - 00:25:00
O tutorial revisa as clases de operación dos amplificadores de potencia, como A, B, AB e C, explicando as súas vantaxes e desvantaxes, así como a importancia de seleccionar a clase adecuada para o deseño específico.
00:25:00 - 00:30:00
Un bo deseño de amplificador de potencia comeza cun modelo non lineal adecuado, que é responsabilidade do fabricante proporcionar. O tutorial menciona a importancia de revisar as follas de datos para obter especificacións clave e parámetros de deseño.
00:30:00 - 00:35:00
Os dispositivos de nitruro de galio (GaN) son destacados por ter unha maior densidade de potencia e eficiencia, e o tutorial presenta un caso de estudo utilizando un dispositivo GaN específico para deseñar un amplificador de potencia de 10 W a 2.4 GHz.
00:35:00 - 00:40:00
A análise de características DC e a selección do punto de polarización son pasos críticos no deseño, e o tutorial guía aos espectadores a través do proceso de simulación e análise para determinar as condicións óptimas de operación.
00:40:00 - 00:45:00
A análise de estabilidade é esencial para garantir que o amplificador funcione de maneira confiable, e o tutorial mostra como utilizar ferramentas de simulación para avaliar a estabilidade do dispositivo en diferentes frecuencias.
00:45:00 - 00:52:28
Finalmente, o tutorial conclúe a primeira parte do proceso de deseño, preparando aos espectadores para a seguinte fase, que incluirá o deseño de redes de adaptación de impedancia e optimización do amplificador.

اعرض المزيد

الخريطة الذهنية

فيديو أسئلة وأجوبة

Qual é o objetivo deste tutorial?
O objetivo é ensinar o design de amplificadores de potência, desde um dispositivo simples até um layout finalizado, incluindo validações para sinais modulados.
Quantas partes tem o tutorial?
O tutorial é dividido em três partes.
O que será abordado na segunda parte?
Na segunda parte, será abordado o design da rede de correspondência e a otimização do amplificador.
Por que a eficiência é importante em amplificadores de potência?
A eficiência é crucial para reduzir custos operacionais e prolongar a vida útil da bateria em dispositivos portáteis.
Quais classes de operação de amplificadores são discutidas?
As classes A, B, AB e C são discutidas, cada uma com suas vantagens e desvantagens.
Qual dispositivo é utilizado como exemplo no tutorial?
Um dispositivo de nitreto de gálio (GaN) da Cree, o CGH 410, é utilizado como exemplo.
Por que os dispositivos GaN são populares?
Os dispositivos GaN têm maior densidade de potência e eficiência em comparação com outras tecnologias.
O que é análise de carga?
A análise de carga é um processo para determinar a impedância ideal para maximizar a eficiência e a potência de saída do amplificador.
Qual é a importância de um modelo não linear?
Um modelo não linear adequado é essencial para prever o desempenho do amplificador durante a simulação.
O que é DPD?
DPD significa pré-distorção digital, uma técnica usada para melhorar a linearidade do amplificador.

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الترجمات

التمرير التلقائي:

00:00:01
hello and welcome to RF design tutorials
00:00:04
this is tutorial 16 on practical power
00:00:08
amplifier Design This is a three-part
00:00:10
tutorial and the current video is part
00:00:13
one of the three remaining two videos
00:00:16
will be posted pretty soon on my YouTube
00:00:19
channel now uh objective of this
00:00:22
three-part tutorial series is to take
00:00:24
you through from a simple device to a
00:00:27
finalized power amplifier layout which
00:00:30
has been validated for One Tone twotone
00:00:32
as well as modulated signal analysis
00:00:36
including performing the digital
00:00:38
predistortion or dpd to obtain uh the
00:00:41
right specs which your PA needs U to be
00:00:46
you know used in any kind of wireless
00:00:47
communication whether it is bace station
00:00:50
um you know handheld terminal Bas PA
00:00:53
design
00:00:54
Etc now before we start subscribe to my
00:00:57
Channel Once you subscribed don't forget
00:00:59
to click on the Bell icon to enable all
00:01:01
the notifications and after you watch
00:01:03
the video kindly give it a thumbs up and
00:01:05
share it with your friends and
00:01:07
colleagues who may be interested in
00:01:08
watching similar
00:01:10
tutorial now as I talked about it will
00:01:12
be a three-part tutorial Series so here
00:01:14
is a quick snapshot of what you can
00:01:16
expect in each of the tutorial in part
00:01:19
one which is this tutorial we will get
00:01:21
started with PA design we will cover
00:01:24
these six Topics in sequence by which
00:01:27
you will by the end of this tutorial you
00:01:28
will have a good source and load
00:01:31
importance for this Creed device and
00:01:33
then in the second part of video we will
00:01:35
start with performing uh the matching
00:01:38
Network design in ideal matching Network
00:01:40
as well as then converting it to a micr
00:01:42
STP based representation and then we
00:01:45
will optimize the PA for fundamental and
00:01:48
harmonic performance and we will perform
00:01:50
the compression and two-tone analysis of
00:01:52
the PA after successful completion of
00:01:55
all these validation we will then
00:01:57
proceed to create a layout for the PA
00:01:59
and then perform em circuit code
00:02:01
simulation to do a final
00:02:03
validation now third part of the video
00:02:06
we'll talk about performing modulated
00:02:08
signal analysis because in today's
00:02:11
Wireless World it is not sufficient to
00:02:13
just do one tone or two tone based PA
00:02:16
validation because the the waveforms
00:02:18
which we are using today has a very high
00:02:21
PPR and with with a higher Peak to
00:02:24
average ratio compression it's always
00:02:26
good to do a modulated signal analysis
00:02:29
to really look and and see how the PA
00:02:32
will perform in a modulated condition
00:02:35
and we will finish off the third part or
00:02:37
this video series of PA design by doing
00:02:40
a digital pre-distortion simulations
00:02:42
inside ads to see how can we improve the
00:02:45
PA linearity to obtain a much better
00:02:48
performance U so that we can get
00:02:51
efficiency as well as a good linear
00:02:53
performance out of our PA design so
00:02:56
hopefully lot of exciting topics and uh
00:02:59
like me you are also excited uh to go
00:03:02
through this journey all right so if
00:03:05
you're ready to take the Deep dive
00:03:06
session uh nothing is you know pending
00:03:09
let's go straight into it now uh why do
00:03:12
we need power amplifier well power
00:03:15
amplifiers are in your transmitting
00:03:17
chain of any wireless system whether it
00:03:18
is a base station mobile phone and any
00:03:21
handheld device they final amplification
00:03:24
stage before your signal is transmitted
00:03:27
therefore they must produce enough
00:03:28
output power to overcome the channel
00:03:31
losses between transmitter and receiver
00:03:34
to make sure the link works um with the
00:03:36
best possible quality now PA is a
00:03:40
typically a primary consumer of power in
00:03:44
any transmitter so major design
00:03:46
requirement on a PA is how efficiently
00:03:49
your PA can convert DC power to the
00:03:52
output RF power now this efficiency uh
00:03:55
translates either into a lower operation
00:03:58
cost if you think about about a cellular
00:04:00
base station where 50% of your
00:04:02
electricity bill might be only due to
00:04:05
the PA operation or in terms of longer
00:04:08
battery life for a handheld device such
00:04:10
as our mobile phone we all will love to
00:04:13
have longer battery life so that we can
00:04:15
you know work on our phones much much
00:04:17
longer or watch videos and do various
00:04:19
things right p linearity is another
00:04:22
important requirement and in there the
00:04:24
input and output relationship must be as
00:04:27
linear as possible so that we can
00:04:29
preserve the signal Integrity of our
00:04:32
signal now these two often are very
00:04:34
conflicting requirement because ideally
00:04:37
you can either have a good linearity or
00:04:39
a good efficiency and a design of PA
00:04:42
often involves a tradeoff of efficiency
00:04:44
and linearity now if you recall my LNA
00:04:47
design tutorial video there the the
00:04:50
trade-off was between noise figure and
00:04:53
the impedance in the input uh written
00:04:55
law similarly in PA you have efficiency
00:04:58
and linearity which are our conflicting
00:05:00
requirement but we will see how how do
00:05:02
we tackle all these challenges and still
00:05:04
do a pretty good um Power Amplifier
00:05:08
design now in terms of class of
00:05:10
operation I'm I'm assuming all of you
00:05:12
already know about the basic theory of
00:05:15
uh Power amplifiers but still for the
00:05:17
sake of completion and making sure we
00:05:19
are all in sync I have a couple of
00:05:21
slides here so the typically uh Class A
00:05:25
operation is is like what you call as
00:05:27
midpoint operation where you buy your
00:05:29
transistor device at the midpoint or
00:05:32
what we call as idss by 2 and have a
00:05:35
full 360° conduction and here the
00:05:39
theoretical efficiency can be obtained
00:05:42
is as 50% however realistically you have
00:05:45
around
00:05:46
50% uh 20 to
00:05:49
25% my apologies so in class B you have
00:05:52
a lesser heating problem than Class A
00:05:54
because in class A you are operating
00:05:56
full 360° in class B we bias our device
00:05:59
at the cut off point so that you only
00:06:01
have 180° conduction so theoretically
00:06:05
efficiency can reach 78% but you will
00:06:08
have some crossover and Distortion
00:06:09
problem uh due to this hard clipping of
00:06:12
the PA now more practical class is class
00:06:16
AB which is in between Class A and B
00:06:18
that means your device will conduct
00:06:20
anywhere between 180° to 360° depending
00:06:24
on the bias point which you select as
00:06:26
shown in this um picture here so in this
00:06:29
class of operation your conversion
00:06:31
efficiency uh can reach somewhere close
00:06:34
to 50 to 60 or even 65% depending upon
00:06:38
how good uh devices and how good uh
00:06:40
design you can you can perform and
00:06:43
similarly you have class C uh class DF
00:06:47
uh kind of um you know applications and
00:06:49
each one of them have their own pros and
00:06:52
cons uh class DF are often called a
00:06:55
switched mode amplifier because we
00:06:57
intentionally Drive the device into
00:07:00
saturation like a square wave so devices
00:07:03
operates like a switch instead of
00:07:05
operating as a classical transistor now
00:07:08
this onoff nonlinear switching makes the
00:07:10
conduction angle almost to zero and
00:07:12
theoretically you can have 100%
00:07:14
efficiency in Practical there are many
00:07:17
design papers and references which show
00:07:20
around 70 to 75% of efficiency which can
00:07:23
be obtained from class F or inverted
00:07:26
class F kind of
00:07:28
amplifiers now uh if you want to learn
00:07:30
more about these classif operation and
00:07:33
how those that efficiency is obtained
00:07:35
and how can you you know set up those
00:07:37
analysis and simulations in ads on a
00:07:40
device level or on a theoretical level
00:07:43
my colleague Matt oelas has you know
00:07:45
posted plenty of um you know videos
00:07:47
around that topic and I'm providing this
00:07:50
link in the description U below this
00:07:52
video feel free to go and explore there
00:07:54
are a bunch of videos there which is
00:07:56
very going to be very very helpful and
00:07:59
in apart from these videos you also have
00:08:02
lot of um you know nonlinear stability
00:08:04
analysis which is another great feature
00:08:06
in new ads version uh whereby if you're
00:08:10
doing rfic or mmic kind of multi um you
00:08:13
know parallelized kind of amplifier
00:08:16
design they are going to be very helpful
00:08:18
allowing you to do a loop gain based St
00:08:22
nonlinear stability analysis so feel
00:08:24
free to explore on your own now any
00:08:27
design uh of a good PA always starts
00:08:30
with having a good nonlinear model and
00:08:32
it is vendor's responsibility to give
00:08:35
you a good nonlinear model now you can
00:08:37
obtain these models from depending on
00:08:39
which manufacturer you are using and in
00:08:42
this video if you want to follow all the
00:08:44
steps I have shown here I have obtained
00:08:47
this design kit from by registering on
00:08:49
cre website and again I will provide
00:08:52
this link in the description box so that
00:08:54
you can go and register yourself and uh
00:08:57
get the permission from tree to download
00:08:59
download their design kit and use it
00:09:01
inside Adas for your work now this
00:09:04
design kit apart from having this design
00:09:07
kit vendors can also give you data and
00:09:09
you know various other formats and in
00:09:12
case vendor is not helping you you can
00:09:14
have your own nonlinear model
00:09:15
development using tools like keyside IC
00:09:18
capap software which is again very very
00:09:20
popular tool to do your own device
00:09:23
modeling or you can use a measurement
00:09:26
based model such as X parameter which
00:09:28
can be extracted out of nonlinear Vector
00:09:31
Network analyzer offered by kyite but
00:09:34
again depending upon which vendor you
00:09:36
work with what's your application you
00:09:38
can figure out a way but again the
00:09:40
bottom line is you need to have a good
00:09:42
nonlinear model to have a good PA design
00:09:46
which is very predictable so that what
00:09:48
you simulate is what you are going to
00:09:50
see during the measurement now about Gan
00:09:53
devices because uh the device I'm going
00:09:55
to use from tree is a gan device and Gan
00:09:58
devices are very popular these days to
00:10:00
do PA design um mainly because they have
00:10:03
much higher power density compared to
00:10:05
other Technologies so have having higher
00:10:08
power density will allow you to generate
00:10:11
more power in a similar amount of area
00:10:14
as compared to Gallum arsenide also
00:10:16
those devices have a higher impedence
00:10:19
which will make your impedance matching
00:10:20
job much easier and they are higher
00:10:23
voltage devices which reduce the need to
00:10:26
do voltage conversion leading to higher
00:10:28
efficiency operations um you know as a
00:10:31
company or as a as a project now for
00:10:34
this tutorial I have taken this case
00:10:37
study and I'm going to use um a pretty
00:10:39
old K device but it's very popular and
00:10:41
very well matur device uh CGH
00:10:45
410 and now cre even has a second
00:10:48
generation or a newer device for the
00:10:50
same you know kind of um uh
00:10:53
specification extending the frequency up
00:10:55
to 8 gahz this particular device is U
00:10:58
for operation up to uh 6 GHz now we will
00:11:02
Target a word design for around 2.4 GHz
00:11:06
with plusus 100 MHz uh 10 wat output
00:11:09
power which is 40 dbm and these are the
00:11:12
gain and efficiency and efficiency I
00:11:14
would like to have more than 50% because
00:11:17
I'm going to do a class AB kind of
00:11:20
configuration for this um amplifi
00:11:22
tutorial ip3 I'm expecting around 45 dbm
00:11:26
or higher right pretty suitable now
00:11:29
don't get discouraged if you're doing 5
00:11:31
GHz 10 GHz kind of design all the
00:11:34
techniques I'm going to teach you in
00:11:35
this three-part tutorial cies are
00:11:37
equally applicable irrespective of your
00:11:40
frequency so even if you're doing a high
00:11:42
frequency U power amplifier design they
00:11:45
still are very very
00:11:48
valid now before we jump into you know
00:11:51
doing PA design it's always a good idea
00:11:54
to go through the data sheet which
00:11:56
manufacturer provides you and and while
00:11:59
going through the data sheet you know
00:12:01
keep uh looking out for some of these
00:12:04
specification because uh some of these
00:12:06
will give you the Baseline when you do
00:12:09
things like load pull for example so
00:12:11
refering to data sheet you will not
00:12:13
tentatively wear uh to set your source
00:12:16
and load impedances uh to reduce the
00:12:19
iterative effort which you sometime need
00:12:20
to do in load P to get to the right
00:12:23
point also these data sheets will give
00:12:25
you some demonstration uh circuit is
00:12:28
schematic and layout out it will give
00:12:30
you some initial idea of possible
00:12:31
circuit topology which you can expect or
00:12:34
which you can work on however it can
00:12:37
completely change based on how you
00:12:38
design but again it's still a very very
00:12:41
good reference so let's do that let's go
00:12:43
through this data sheet and look at some
00:12:46
of the key um you know specifications or
00:12:49
key you know figure of Merit now here's
00:12:51
the device which I'm using it's a 10 wat
00:12:53
device and that's what I'm designing the
00:12:55
amplifier for a DC to 6 GHz it's a
00:12:59
gallium nitrate as I talked about now if
00:13:02
you look at a small signal gain around
00:13:05
the frequency which we are working is
00:13:07
around 16 DB which is pretty good and a
00:13:10
13 wat typical saturated power so
00:13:13
usually for Gan devices it's like a 3db
00:13:16
you know saturated power what they
00:13:18
mention 65% efficiency at Pat and
00:13:23
usually the vendors will always mention
00:13:26
train efficiency not the power added
00:13:28
efficiency see so as a designer you need
00:13:30
to distinguish it very very carefully
00:13:33
now usual power Amplified specs are
00:13:36
written for power added efficiency which
00:13:38
will be slightly lower than the drain
00:13:40
efficiency and it's recommended for 20
00:13:43
volt oper 28 volt operation which is
00:13:45
perfect what we are trying to do and
00:13:48
also in terms of application if you look
00:13:50
at it is applicable for Broadband
00:13:53
cellular Class A ab and Linear Amplifier
00:13:56
suitable for ofdm and that's perfectly
00:13:59
what we want because we want to do class
00:14:01
AB amplifier design for 5G application
00:14:05
which is typically an ofdm system all
00:14:08
right so that's the first thing and then
00:14:09
you get your DC uh operating points and
00:14:12
DC conditions and here's your typical
00:14:16
range for uh the gate um you know bias
00:14:19
and I'm going to use minus 2.7 anyways
00:14:22
but we'll figure out uh how did I arrive
00:14:25
at minus 2.7 volt not only by looking at
00:14:28
the data sheet but actually doing the IV
00:14:31
characteristics now let's scroll down
00:14:34
and there are various plots of
00:14:36
compression gain and and all that but
00:14:39
let me reach to this point so at this
00:14:42
you know page here you can see uh vendor
00:14:45
is recommending or providing information
00:14:48
about the the best possible source and
00:14:50
load impedances versus frequency for
00:14:54
getting the best possible power but
00:14:56
again uh remember these um imp idence
00:14:59
specification are always mentioned with
00:15:02
respect to um you know the the bias
00:15:06
condition and if you change it bias
00:15:08
condition they may not be valid but
00:15:10
again it's a good reference or good
00:15:12
reference point so Z Source um around
00:15:15
our frequency you know an aggregate
00:15:18
magnitude is around 5 ohm and if you
00:15:21
look at about load is around 20 ohm or
00:15:23
so so that's a pretty good Baseline and
00:15:26
this information will be very useful
00:15:28
when we reach u a load uh load pull
00:15:31
point so keep take a note of this uh
00:15:34
here all right similarly if we go keep
00:15:37
going further down you can see a demo
00:15:39
board which vendor can also give you and
00:15:42
you see how the PA is mounted and this
00:15:45
is how typically how all high power PAs
00:15:49
will be assembled so you will have a
00:15:51
metal flange and you will Mount this
00:15:53
device directly on that flange and now
00:15:56
there are two kind of packages which Fe
00:15:58
es available one could be a screw down
00:16:01
type package another could be like a
00:16:03
solder kind of package but that's pretty
00:16:05
popular way of doing the P assembly
00:16:08
because you don't want this high power
00:16:10
to be consumed on top of PCB uh like how
00:16:13
can we Mount the device for low power or
00:16:16
the medium power or LNA uh kind of
00:16:19
application and also um you know how do
00:16:21
you do this PCB design is very
00:16:23
subjective I have seen um you know many
00:16:26
designers they keep the input part of
00:16:28
the PCB and output part of the PCB
00:16:31
completely separate and they have this
00:16:34
flange going all the way down or
00:16:36
sometime you can have the single PCB
00:16:38
with a cutout for this device mounting
00:16:41
so again it's user Choice uh nothing is
00:16:43
good or bad it depends how you would
00:16:46
like to you know implement it now if we
00:16:49
go to the next page here we can see a
00:16:52
picture of a demo amplifier circuit is
00:16:54
schematic and it gives you some basic
00:16:56
idea about the kind of decoupling uh
00:16:59
they have used uh the input matching and
00:17:01
the stability Network and as well as the
00:17:03
output matching network uh for the PA
00:17:07
now lot of time you don't need to
00:17:08
blindly follow these many capacitors um
00:17:11
and all that because usually vendors
00:17:13
will always do a Broadband you know kind
00:17:16
of board design and they will
00:17:19
overcompensate um you know by putting
00:17:21
lot of extra things to make sure the
00:17:24
device shows as good performance as as
00:17:27
possible but in real application you you
00:17:30
really may not need these many bypass
00:17:32
capacitors and so on but again that
00:17:35
decision is left to designer depending
00:17:37
upon how noisy they expect their power
00:17:39
supplies to be and accordingly they can
00:17:41
take a call but a good point to to note
00:17:44
here uh the lowest um capacitance which
00:17:47
is means the higher frequency U will
00:17:50
always be closest to your you know
00:17:53
transistor the the bigger value or the
00:17:55
biggest value will always be closer to
00:17:57
the D
00:17:58
so that it can compensate for a low
00:18:01
frequency humming which might be you
00:18:04
know coming via power supply all right
00:18:07
so that gives us some idea initial idea
00:18:09
what to expect you can see some cies
00:18:11
resistance here used to stabilize the
00:18:13
device although it's pretty big value uh
00:18:15
which I would like to avoid personally
00:18:18
and then there are a couple of
00:18:19
placeholders as zero ohm resistors which
00:18:22
which can be used in case it is
00:18:24
necessary and then you have some
00:18:26
coupling capacitors here all right so
00:18:29
that's good enough information so always
00:18:31
keep um you know pay equal attention to
00:18:33
the data sheet because as I said you can
00:18:36
get a lot of useful information coming
00:18:37
out of this data sheet which serves as a
00:18:40
baseline uh for your real circuit design
00:18:44
now let's directly jump in to ads here
00:18:48
so in ads we um we are going to talk
00:18:50
about this part one and I will take you
00:18:54
to all the key steps which I mentioned
00:18:57
in the in the OR additional slide here
00:18:59
so let me go back to that slide so that
00:19:01
we can keep track all right so in part
00:19:03
one uh I already provided you about the
00:19:06
introduction and classif operation now
00:19:09
let's start with our second step where
00:19:12
we are going to perform DCI
00:19:14
characteristics and a bias Point
00:19:16
analysis for our device now here with
00:19:19
this uh template um I already covered
00:19:22
all these uh videos how to perform dciv
00:19:26
simulation how to perform stability
00:19:28
analysis in my previously posted videos
00:19:31
so I'm assuming that you have seen all
00:19:33
those tutorial videos already if you
00:19:36
have not please go ahead and see those
00:19:38
videos first before you continue with
00:19:40
this um you know uh topic here because
00:19:43
very difficult to explain all those
00:19:45
Basics when we are talking about how to
00:19:47
do a power amplifier design right so
00:19:50
here the template I have used um can be
00:19:53
obtained from insert template and here I
00:19:55
have used a fit uh curv Tracer template
00:19:58
which I already talked about in the
00:20:00
earlier video so once you have the
00:20:02
template you click okay you will have a
00:20:04
skeleton something like this available
00:20:06
on your schematic and now you can
00:20:08
connect your device uh from the library
00:20:11
so here you can see on the left hand
00:20:13
side I have install the key uh cre
00:20:15
library and how do we install Library uh
00:20:18
or window Library into Adas well you can
00:20:21
go to design kit manage library and
00:20:24
browse to the location where you have
00:20:26
kept the lip. def or where you have
00:20:29
unarchived the the library which you
00:20:32
obtained from vendor's website right so
00:20:36
here all these Basics are already
00:20:38
covered but I just gave you a refresher
00:20:40
so here you can see the CGH 400 uh one Z
00:20:44
device this is my gate bias from min-2
00:20:48
to minus 4 pretty much like how it was
00:20:50
referred in data sheet and here is the
00:20:52
drain bias now notice in drain bias I'm
00:20:56
sweeping from 0 to 7 70 volts while this
00:21:00
device is only 28 volts so somebody
00:21:02
might be wondering why are we going to
00:21:04
70 volt well a good tip always in power
00:21:08
amplifier because you are going to plot
00:21:10
the load line and and and those kind of
00:21:12
stuff it's always recommended to sweep
00:21:15
the train voltage at least two times of
00:21:17
your desired operating voltage and I'm
00:21:20
going to use 28 volt so ideally I should
00:21:23
have gone to 56 volt but anything extra
00:21:26
which you add it's it's more than
00:21:28
welcome all right so let's go ahead and
00:21:30
perform simulation and now we will have
00:21:33
a data display with this template now as
00:21:36
I talked about earlier my colleague
00:21:38
matelis has those PA videos and I'm
00:21:43
operating you know using one of the
00:21:45
templates which is provided in his um
00:21:49
you know first session which is Class A
00:21:51
ab and B um you know uh tutorial so once
00:21:56
I obtain the workspace I'm only using
00:21:58
the one of the data display templates
00:22:01
because it has lot of equation already
00:22:04
implemented which makes my job easier
00:22:06
now here one marker is posted on idss
00:22:09
point as you would expect and the based
00:22:11
on the second marker you will have
00:22:13
voltage and current waveforms the power
00:22:16
dissipation and this table showing you
00:22:18
the output power small signal gain large
00:22:21
signal gain efficiency uh DC current
00:22:25
conduction angle duty cycle all these
00:22:27
things are updated now notice uh usually
00:22:30
you will obtain this voltage and current
00:22:32
waveforms by doing a harmonic balance
00:22:34
simulation but here uh using the
00:22:36
equation uh which my colleague has
00:22:39
implemented we are able to estimate all
00:22:41
those uh from the load line based design
00:22:45
equation so they are estimation they are
00:22:47
not exactly what harmonic balance will
00:22:50
show show you but it's a very very good
00:22:52
and accurate um you know um post
00:22:55
processing now based on where you keep
00:22:57
keep your you know operating condition
00:23:00
with marker two you can see the waveform
00:23:02
is changing the conduction angle is
00:23:04
changing and rest of the parameters are
00:23:06
changing so if I operate my device on
00:23:09
class P um you know where you have
00:23:12
conduction angle of 180° you can see the
00:23:15
efficiency goes up and here is the power
00:23:17
consumption which is only happening due
00:23:19
to this 180° uh conduction of your of
00:23:22
your current and it's clipping um in
00:23:26
half of the cycle but again so depending
00:23:29
upon where you place it for example if I
00:23:31
place it in class A configuration you
00:23:33
can see conduction angle is 360° and you
00:23:36
have the full 360° current and voltage
00:23:39
and then power dissipation is all
00:23:41
continuous right so based on my
00:23:44
understanding referring to data sheet I
00:23:46
have uh selected 28 volt uh operation
00:23:50
with minus 2.7 uh es gate voltage which
00:23:54
will um you know approximate it to give
00:23:57
me large signal gain of 12 DB and if you
00:24:00
remember our spec we wanted gain of more
00:24:02
than 10 DB which is pretty good the
00:24:05
efficiency is close to
00:24:07
46% as estimated by just simply the DC
00:24:11
analysis but once we do load pull and we
00:24:14
find the right um you know Optimum load
00:24:16
operating point this efficiency will
00:24:19
easily cross over 50% no problem and
00:24:22
also the output power predictor is
00:24:24
around 36 dbm and again with the right
00:24:27
you know power match impedence matching
00:24:30
we would be able to get easily more than
00:24:32
40 uh DPM so it's all in all it's a
00:24:35
pretty good operating point where I am
00:24:38
expecting to have 256 de of conduction
00:24:42
angle which results in around 70% of
00:24:45
duty cycle so that finishes step number
00:24:48
one of finding the right DC operating
00:24:51
Point uh for your power device now we
00:24:55
take that information and we Pro proceed
00:24:58
to next step so what's our next step is
00:25:01
to perform the stability analysis right
00:25:04
so in a stability
00:25:05
analysis uh here I'm using uh instrument
00:25:09
kind of look and feel and this kind of
00:25:12
component can be obtained uh from going
00:25:15
to simulation instrument pallet and here
00:25:18
I do have this SP uh Network analyzer or
00:25:22
NWA component which will give you look
00:25:24
and feel of network analyzer and you
00:25:27
have of input and output to be connected
00:25:30
and the bias is inside and you can just
00:25:32
set these parameters which you want now
00:25:35
internally you know it's just a visual
00:25:37
appeal but internally is the is the same
00:25:40
kind of bench which you uh will end up
00:25:43
creating yourself you can see there's
00:25:46
input termination DC block DC feed and
00:25:49
you have V bias 1 V bias 2 and that's
00:25:52
where your device will get connected uh
00:25:54
here all right so just for the you know
00:25:57
sake of iand or introducing you to a new
00:26:01
kind of virtual instrument which you can
00:26:03
get in areas so I connected this device
00:26:06
um we will set the same bias which we
00:26:09
computed of minus 2.7 volt to 28 volt
00:26:13
and I'm going to analyze this device
00:26:15
from .5 GHz to 6 GHz which is the
00:26:19
maximum frequency recommended now here
00:26:21
I'm using some data display templates um
00:26:24
because I don't want to even you know
00:26:27
prepare more own graphs or write some
00:26:29
equations to to calculate the stability
00:26:32
Factor Etc now how can you get access to
00:26:35
this uh kind of data display template
00:26:37
well if you go to any Simulator for
00:26:39
example as parameter or anything you
00:26:42
have this component here called display
00:26:44
template if you place this display
00:26:47
template component onto schematic you
00:26:49
can double click and you can browse to
00:26:52
installed templates and under product
00:26:56
you will have lot of these preconfigured
00:26:59
templates which you can use and all of
00:27:02
them are like data display templates
00:27:04
where they will have certain number of
00:27:06
plots or equations written already to do
00:27:09
your job so from the list available I'm
00:27:12
using S21 plot uh network analysis plot
00:27:15
and also the the stability Circle and
00:27:19
the you know gain stability circles Etc
00:27:22
so see what happens once I have this
00:27:24
template and if I perform the simulation
00:27:27
I get all these kind of plots and if you
00:27:30
refer at the bottom uh here we get
00:27:32
multiple tabs uh depending on the
00:27:35
templates I'm using so here one page per
00:27:38
template and we can look at the
00:27:40
stability circles and you can clearly
00:27:43
see your device is not stable at the the
00:27:47
2.4 GHz where my marker is or where my
00:27:51
frequency selector marker is and if I
00:27:53
change this marker you will see those
00:27:55
stability Circle points change change
00:27:58
and it shows you uh what kind of
00:28:00
stability performance you have for that
00:28:02
device so obviously uh you know till
00:28:05
around 4 gahz you can see I'm less than
00:28:09
U you know factor of one with mu load or
00:28:12
mu source and if any one of them is
00:28:14
greater than one my device will become
00:28:16
unconditionally stable and also the role
00:28:19
at stability factor or what you call as
00:28:21
K is less than one so clearly our device
00:28:24
is not stable at around 2.4 GHz so let
00:28:28
me place this marker closer to
00:28:31
2.4 GHz here and you can see the
00:28:35
stability circles are cutting the SM
00:28:38
chart now how to stabilize the device
00:28:40
again taking Q from the from the data
00:28:44
sheet um I knew there is a series
00:28:47
resistor which can be placed to
00:28:49
stabilize this device now like we
00:28:52
discussed in LNA video where I said
00:28:55
don't place any resistive device at the
00:28:57
input of the transistor because in case
00:29:00
of LNA it affects your noise figure
00:29:02
performance it distorts it in case of
00:29:05
power amplifier uh try avoiding placing
00:29:08
any resistive component in the output
00:29:11
stage or in the drain terminal because
00:29:14
that will suck up all the gain which you
00:29:16
have obtained by some amount and it's in
00:29:19
power stages it's very difficult to
00:29:21
obtain gain and anything which you have
00:29:23
obtained you would not like to sacrifice
00:29:26
by putting a resistor plus that resistor
00:29:29
will need to be of much higher wattage
00:29:32
because you're are going to produce a
00:29:33
higher power so it's always a good
00:29:36
choice to place a resistor at the input
00:29:38
of any power amplification device now
00:29:42
with this 5 Ohm resistor if we go ahead
00:29:44
and perform simulation now you can see
00:29:48
uh my stability factor is greater than
00:29:51
one and it's actually greater than two
00:29:54
and now the load and and Source
00:29:56
stability circles are are outside the
00:29:58
smart that means at around 2.4 GHz my
00:30:01
device is unconditionally stable and
00:30:04
actually um if you look at here from 1
00:30:07
gahz onwards your device is a Broadband
00:30:10
stable so if you have to work in
00:30:12
anywhere in this zone now you can
00:30:15
confidently go and design your matching
00:30:17
network is already you know kind of
00:30:20
stabilized all right so that was step
00:30:22
number two so we worked on and
00:30:24
stabilized our device at the operator
00:30:27
region we are working at and we only Ed
00:30:30
5 Ohm resistor now when we use 5 Ohm
00:30:33
resistor it's not only a you know good
00:30:35
idea to only keep looking at stability
00:30:38
Factor you need to be also concerned
00:30:40
with how much cane has dropped due to
00:30:43
that resistor and here if you look at
00:30:46
this parameter performance and if I
00:30:49
place a marker around 2.4 gahz I can see
00:30:53
I have an unmatched gain of around 11 DP
00:30:56
which is pretty pretty good and it's a
00:30:58
small signal gain and once I do
00:31:00
impedence matching Etc my gain will be
00:31:03
even more and my requirement is anyway
00:31:05
to have more than 10 DB gain so that's
00:31:09
pretty good so my resistor hasn't
00:31:11
affected too much of my performance but
00:31:14
it has a stabilized my device good
00:31:17
enough all right so let's go ahead into
00:31:20
the next stage of our PA design process
00:31:24
and the next stage obviously is to
00:31:26
perform a load pull right and I already
00:31:30
posted three videos on load pull please
00:31:33
um make sure you watch the load poo
00:31:35
videos before you continue here because
00:31:37
I'm not going to explain the
00:31:38
fundamentals of load p and how do you
00:31:41
understand data from load pull now the
00:31:44
template which I'm using here is simply
00:31:46
obtained as I demonstrated in tutorial
00:31:48
videos by going to design guide load
00:31:51
pull one tone load pull and constant
00:31:54
available Source power because that's
00:31:56
always your getting started load pull
00:31:59
now once you bring out this template I
00:32:01
have connected the stabilized device
00:32:04
provided the right DC bias as we uh
00:32:07
finalized the RF power is 2400 mahz now
00:32:12
output power which I'm expecting is 40
00:32:14
TBM and we just noted the gain is around
00:32:17
11 DB or so so the input power I have
00:32:21
decided to feed is 29
00:32:23
dbm now the Z load uh fundamental is
00:32:27
kept around 20 ohm and where we got this
00:32:30
information from well remember this data
00:32:33
sheet there was a page where you had the
00:32:36
the source and a load impotance divided
00:32:38
here so I just selected 20 ohm as um you
00:32:42
know one of the points and also remember
00:32:44
this Z Source fundamental I kept it as 5
00:32:48
ohm so again in this data sheet if you
00:32:51
refer to that's the kind of U you know
00:32:53
impedence you looking at so even if you
00:32:56
know the vendor is not giving you uh the
00:32:59
source impedence information for some
00:33:00
reason for any Gan device selecting 5 to
00:33:03
10 ohms is always a good choice and if
00:33:07
you are using LD Moss again 5 ohm or so
00:33:10
is kind of good choice there right but
00:33:13
more information you can get um from the
00:33:16
data sheet is always better now the
00:33:18
second and third harmonic of the load I
00:33:21
have you know terminated into open
00:33:23
circuit or you can decide to terminate
00:33:25
into a short circuit yeah and so that we
00:33:28
can look at the fundamental performance
00:33:31
there or you can even perform harmonic
00:33:34
load pull all those templates are
00:33:36
already available uh there but when you
00:33:38
are starting with your first um you know
00:33:41
load pull is always good idea to
00:33:43
terminate it either in a open circuit or
00:33:46
a short circuit now once we go ahead and
00:33:48
perform this load pull we can see um The
00:33:52
Contours and here um you know uh we can
00:33:55
see we have we are able to achieve more
00:33:58
than 40 dbm of power from our device and
00:34:02
efficiency which is much higher than 50%
00:34:05
so probably it was a good Zone to
00:34:07
perform load pull so we already have all
00:34:10
the data here again as we discuss in
00:34:12
load pool video you have the condition
00:34:15
which is giving you the maximum power as
00:34:17
well as cane which is around 12.5 DB and
00:34:21
also the operating condition which can
00:34:23
give you the maximum pae and these are
00:34:26
the load points where you can vary the
00:34:28
marker and see the operating condition
00:34:31
pae uh output power and so on now here
00:34:35
you have a decision to make because
00:34:38
using the load pull which we perform we
00:34:41
are able to get uh the desired output
00:34:43
power as well as efficiency so you can
00:34:46
either use this um impedence
00:34:48
specification of said load and you can
00:34:51
see it is also giving you the input
00:34:53
impedence so you really don't need to
00:34:55
perform a source pull in order to get
00:34:58
you the best gain or to find the right
00:35:00
source impedence for your PA Design One
00:35:03
template is giving you everything
00:35:05
because often I get a query how to do
00:35:07
Source pull Etc if you want to do Source
00:35:10
P the template is available but Frankly
00:35:12
Speaking you really don't need to unless
00:35:15
there is a you know something which is
00:35:17
not you know um given to you by this
00:35:20
template so again if even if you look at
00:35:22
the maximum pae operation which is
00:35:24
around 65% yes still able to get very
00:35:27
close to what you're looking at in terms
00:35:30
of output power so you can either select
00:35:33
this Z load and Z Source combination or
00:35:36
you can select this uh Z source and Z
00:35:39
load combination and you can proceed for
00:35:42
impedance matching Network design from
00:35:44
here but the question is uh is it uh
00:35:48
recommended to go directly jump into
00:35:50
impedence matching because you are able
00:35:53
to operate the output power but right
00:35:55
now you don't know how much DB
00:35:56
compression you are operating on you
00:35:59
don't know how much IMD uh level you are
00:36:01
going to get Etc so again depending upon
00:36:05
what you are looking for you can go back
00:36:08
to adss schematic and you can utilize
00:36:11
the other templates which I also talked
00:36:13
about in the early video so you can
00:36:16
sweep the available Source power you can
00:36:18
see how much compression level you are
00:36:20
working at you can display Contours at a
00:36:23
specific xtb compression point and if
00:36:27
acpr or evm is your concern you can also
00:36:30
plot Contours of acpr or evm at a
00:36:34
specific output power or at a specific
00:36:38
xtb gain compression similarly you can
00:36:41
even do two-tone uh load pull simulation
00:36:44
because if IMD is your Prime concern you
00:36:47
can also get IMD Contours if you do two
00:36:50
to on load P but here I'm showing you a
00:36:53
way how to how to avoid doing all those
00:36:56
and directly utilize the latest
00:36:59
available templates to still get your
00:37:01
job done before you end up confusing
00:37:04
yourself but this fundamental load pull
00:37:06
was very important because we need to
00:37:08
make sure we have the right power as
00:37:11
well as right efficiency all right so we
00:37:13
got this information we got our area
00:37:16
where we need to work on now what's the
00:37:18
next step to do your PA design or to
00:37:21
progress with your PA design now
00:37:23
remember in the last load pull tutorial
00:37:26
video I showed you how to use graphical
00:37:29
methods of um Computing the recommended
00:37:32
load points and then we use those load
00:37:36
points into an xdb compression template
00:37:40
and I also provided a knowledge center
00:37:42
link for you to download uh the
00:37:44
workspaces created by my colleague Andy
00:37:47
Howard so I'm using one of those
00:37:50
templates which I demonstrated in the
00:37:52
last video here I already used the
00:37:55
graphical loot pull uh method because I
00:37:58
I knew from my first load pull
00:38:00
simulation which zone to look at now I
00:38:03
went to that zone selected the area and
00:38:06
I exported only those load points and as
00:38:10
an MDF file and now I'm going to perform
00:38:14
load pull only on those uhu you know
00:38:16
points as necessary which could be a
00:38:19
much a smaller zone now for this load
00:38:22
pull I have terminated my source idence
00:38:25
to the complex conjugate of what we
00:38:28
calculated in the earlier uh you know
00:38:31
analysis of load pull because this will
00:38:33
give you the maximum gain if you
00:38:35
terminate your Source ter you know um
00:38:39
Source termination into the complex
00:38:41
conjugate of what you obtain from the
00:38:43
load pool now input power I'm selecting
00:38:47
as 28 dbm and 3db is my target operating
00:38:51
range rest of the parameters is already
00:38:54
set now as we we discussed we can start
00:38:57
optimization and now this template will
00:39:00
make sure all the Contours all the data
00:39:03
shown to you in the load pool only
00:39:06
belongs to around 3db compression
00:39:09
characteristics so it will filter out
00:39:12
everything which is highly compressed or
00:39:14
which is under compressed it is only
00:39:16
going to give me the details which are
00:39:20
relevant for me to get to a 3db
00:39:23
compression point now if you're looking
00:39:25
to do 1db compression Point based design
00:39:28
feel free to change it to one and then
00:39:31
you can still use the same template as
00:39:33
it is there is no change there but
00:39:35
typically in G amplifiers we we talk
00:39:38
about 3dp you know kind of gain
00:39:41
compression value so this will take few
00:39:43
seconds for uh for the simulation to run
00:39:46
but again as you can see I have simply
00:39:48
inserted uh my cre device along with my
00:39:52
stability resistor and nothing else has
00:39:55
to be changed so it's like just drop in
00:39:57
your device um you know set up some key
00:40:00
parameters and you hit the optimization
00:40:03
button and let ads do your job so now
00:40:05
the simulation is finished now I will
00:40:08
have a data display showing me the the
00:40:11
right format of data or the value which
00:40:14
I'm really interested in so here in the
00:40:17
center you can see the Contours
00:40:20
belonging to 3db operating condition of
00:40:23
this device here is the efficiency and
00:40:26
here is the various power levels of
00:40:28
various Contours and also gain you can
00:40:31
see is around 13 TB which is which is
00:40:34
kind of pretty good uh obtain now the
00:40:37
final information is simply contained in
00:40:40
the tables uh which are shown here the
00:40:43
red one is showing you the maximum pae
00:40:46
operation and the blue one showing you
00:40:48
power delivery again I already discuss
00:40:50
all of this in the previous load poool
00:40:53
tutorials so take away from me here
00:40:55
again for a 3db operation where I'm
00:40:58
getting more than 40 dbm power and
00:41:01
efficiency of around
00:41:03
57% this is my Zed load which I need to
00:41:06
design impedance matching for and this
00:41:08
is the Z in for which I need to do the
00:41:11
input in input impedence matching
00:41:14
Network and again if you want to go
00:41:16
behind highest deficiency which is
00:41:18
66% and even you go behind it you can
00:41:22
see you are still able to operate you
00:41:24
know get more than 40 DB M so these are
00:41:27
your impedence matching um you know
00:41:29
targets and again both of them are
00:41:31
pretty close so there is nothing more so
00:41:33
which is a good sign that this device
00:41:35
will give me the best possible
00:41:38
efficiency with the best possible output
00:41:40
power and I would be able to meet my
00:41:43
design requirements by a by a good
00:41:45
amount and also the large signal gain is
00:41:48
is more than 12 DB against my target of
00:41:51
10 DB which is again a good news for me
00:41:54
so all in all pretty good so I got my
00:41:57
load impedence as well as Source
00:41:59
impedence uh from this analysis now what
00:42:02
do we need to do next what are you going
00:42:05
to do next well the next requirement of
00:42:08
course is to do impedence matching now
00:42:11
before we go into impedence matching
00:42:14
which actually will lead us to the
00:42:16
second part of this video or second
00:42:18
tutorial which I will post in next few
00:42:21
days before we go there just one final
00:42:24
step which I always like to
00:42:26
do is to create this kind of schematic
00:42:29
where I check my impedence matching
00:42:32
requirement and I perform harmonic
00:42:34
balance simulation as well as as
00:42:36
parameter simulation just to get a sense
00:42:39
of how a perfectly matched power
00:42:42
amplifier would look like for me all
00:42:45
right so in this case rest everything is
00:42:47
still the same I have the same um RF
00:42:51
frequency you know bias condition input
00:42:54
power is set as per what we just now
00:42:56
from load pull and notice these two
00:42:59
variables here Zs is set to the complex
00:43:03
conjugate of what we just obtained
00:43:06
always remember that whatever load pull
00:43:08
gives you you need to do a complex
00:43:10
conjugate of this and use that number in
00:43:13
your Source termination the load
00:43:16
termination has to be used as it is you
00:43:19
don't need to take a complex conjugate
00:43:21
of this so once we have these variables
00:43:24
set but before we assign those numbers
00:43:27
to these termination I just want to see
00:43:30
in a 50 ohm operation how my PA will
00:43:33
perform and here I do have bunch of um
00:43:36
equations Computing my power delivered
00:43:39
in Watts power delivered in dbm the
00:43:43
input power the DC power then I'm
00:43:46
commuting the power added efficiency as
00:43:49
well as I'm Computing the train
00:43:51
efficiency so that we can match that
00:43:53
efficiency number from the data sheet if
00:43:56
required and then based on power
00:43:58
delivered and power available using
00:44:01
these equation I will be able to do a
00:44:04
large signal gain um you know
00:44:06
calculation so instead of relying on
00:44:08
graphs Etc I have written this equation
00:44:11
and again these equations are available
00:44:14
as a part of template or you could
00:44:16
simply write it yourself now IL load V
00:44:19
load all these are name of these nodes
00:44:22
you can see there is a current probe
00:44:24
here and all of these have been named
00:44:26
properly so if you try to replicate this
00:44:29
kind of template or equation on your
00:44:32
side make sure you modify my equation
00:44:35
based on the names which you're using at
00:44:38
your side all right okay so let's go
00:44:41
ahead and see how this device operates
00:44:43
in a 50 ohm now here is the output power
00:44:46
Spectrum you can see the output you know
00:44:49
power on this graph is around 38 TBM and
00:44:53
same thing is predicted by my equation
00:44:55
for for now and then you have a power
00:44:58
added deficiency which is around 40% now
00:45:01
remember the first DC analysis we did
00:45:04
this is what DC analysis predicted
00:45:06
around
00:45:08
36% uh or something like that efficiency
00:45:11
and that is what we are getting the
00:45:13
drain efficiency obviously is slightly
00:45:15
higher large signal gain is around 9 DB
00:45:19
in power output in wats is around 6.3 DP
00:45:23
and these are your small signal gain and
00:45:25
small small signal uh input and output
00:45:28
matching and these two are current
00:45:31
waveforms uh the VDS SII now uh remember
00:45:35
we talked about intrinsic voltage and
00:45:38
current information now depending upon
00:45:40
which device vendor uh device you are
00:45:43
using when you simulate as a part of
00:45:46
data set uh they will um you know also
00:45:50
give you some things like IDI which is
00:45:53
intrinsic drain current and also also
00:45:56
the voltage which is
00:45:58
vdsi which is intrinsic gate voltage so
00:46:01
if you want to plot the dynamic load
00:46:04
line Etc you should be using these
00:46:07
voltages rather than you know uh
00:46:10
plotting the dynamic load line Etc using
00:46:13
this voltage and this current because
00:46:15
vdsi and IDI shows you how is the
00:46:19
voltage in current inside this device
00:46:21
right at the train terminal of your
00:46:24
gallium nitrate transistor so they show
00:46:26
you the true picture of how much your
00:46:29
fet is conducting because anything which
00:46:32
you get at outside at the load
00:46:34
termination point is you know when your
00:46:36
signal has already transitioned through
00:46:38
package and and you know some of those
00:46:41
parasitics are already included but
00:46:44
intrinsic voltage and current gives you
00:46:46
exactly what's happening at the terminal
00:46:48
of a gate so imagine you open the fet
00:46:51
and put a probe right at the train
00:46:53
terminal of your device so this is very
00:46:56
very useful you should look at it now so
00:46:59
that was 50 ohm operation of course we
00:47:01
expect that now let's change this to ZL
00:47:05
which is what we obtained from load
00:47:07
poool and complex conjugate of the
00:47:10
source impedence now this is you know
00:47:13
creating a condition where your
00:47:14
amplifier is perfectly matched for
00:47:17
fundamental frequency not for the
00:47:20
harmonic frequency yet it is only a
00:47:22
fundamental frequency so your harmonics
00:47:25
will also see the same terminations
00:47:28
which is not Optimum remember in load
00:47:30
pull you set it to either open circuit
00:47:33
or short circuit here your harmonics are
00:47:36
also going to see the same Source
00:47:38
frequency same load frequency so let's
00:47:41
see what happens so we'll go ahead and
00:47:43
analyze this and I'll look at the table
00:47:46
there so output power as predicted by
00:47:49
loot pull is you know around 41 or
00:47:52
higher dbm efficiency is around 56% %
00:47:56
drain efficiency is 60% which is very
00:47:59
close to what was mentioned in the data
00:48:01
sheet of of the device here if you go to
00:48:04
the first page so we are we are able to
00:48:07
operate pretty close to what has been
00:48:10
you know um showed to us in data sheet
00:48:12
pretty good the last signal gain is
00:48:14
around 12.5 DB this is what exactly our
00:48:17
load pull was saying and output power
00:48:19
delivered is around 13 watt and this is
00:48:22
what your data sheet also talks about 13
00:48:25
watt of typical pad right so all in all
00:48:28
everything is falling into place pretty
00:48:30
nicely now here is the difference so
00:48:33
don't confuse yourself when you look at
00:48:35
this spectral plot and if you put a
00:48:38
marker there it is reading 38.7 dbm
00:48:42
power whereas this is showing 41 dbm so
00:48:45
what's the difference between two now
00:48:47
when you use dbm function in these plots
00:48:50
it is always referring to 50 ohm as a
00:48:53
reference impedence to do your power
00:48:56
computation however if you remember the
00:48:58
P delivered um you know equation here it
00:49:02
is it is reading your instantaneous node
00:49:05
voltage and the current and that is
00:49:08
based on the ZL specification so that's
00:49:12
normalized or calculated as per this
00:49:14
impedence not the 50 ohm and you know
00:49:17
this impedence is not 50 ohm because
00:49:19
this is 28 +
00:49:21
j.5 all right so there'll be always well
00:49:24
you know this kind of discrepancy unless
00:49:27
you un normalize this dbm calculation to
00:49:30
the load impedence which you are using
00:49:32
so be mindful of that and don't end up
00:49:35
confusing yourself right so here is the
00:49:38
the voltage and current you know profile
00:49:41
after you terminate the device into nice
00:49:44
matching condition which you are looking
00:49:46
for and here is your gain small signal
00:49:49
gain which is going to be around 15.6 TB
00:49:53
and if you go back to data sheet
00:49:56
this is what roughly we are estimating
00:49:58
around 2 GHz so it's a perfectly
00:50:00
matching condition and the output match
00:50:03
not so great because we went for power
00:50:06
match remember we haven't gone for
00:50:08
simultaneous conjugate match we have
00:50:11
gone to mash the device to the best
00:50:14
possible uh you know power uh condition
00:50:17
and again this is a small signal match
00:50:20
this is not a large signal match but
00:50:23
looking at this power we can confidently
00:50:25
say it's a good large signal match
00:50:27
because we are able to extract the
00:50:29
maximum power and you know maximum power
00:50:32
can only be delivered if you do a
00:50:33
complex conjugate match but that is
00:50:36
large signal matching not a small signal
00:50:40
what you call as um you know s22 and
00:50:42
there are templates available inside
00:50:44
areas to do large signal S11 large
00:50:47
signal s22 if you want to do that but
00:50:51
for now I'm only doing things which are
00:50:53
shown to you in data sheet and they
00:50:55
always show you small signal matching
00:50:57
conditions here all right so going back
00:51:01
uh to our you know agenda for this part
00:51:04
of tutorial we covered we went through
00:51:08
the PA introduction classes of operation
00:51:11
dciv and bias Point analysis we looked
00:51:14
at a stability analysis performed the
00:51:16
initial load pull and then we went ahead
00:51:19
and perform a 3db based load pull to
00:51:21
finalize our right source and load
00:51:23
impedence and finally did a validation
00:51:26
of source and load impedence which we
00:51:28
found in Step number five in a in a PA
00:51:32
operating mode and make sure if we do
00:51:34
the right impedence matching we will get
00:51:37
all the design specification as we are
00:51:40
looking at and that would lead us to
00:51:42
part two of this video where we will
00:51:44
continue this learning and we will
00:51:48
Design the input and output matching
00:51:49
Network and there are plenty of good
00:51:52
tips and tricks which you need to know
00:51:54
by for doing a right matching Network
00:51:57
design for PA amplifier you know PA kind
00:52:00
of operation and we are going to talk
00:52:03
about that in part two video and then we
00:52:06
will finalize the PA by optimizing it
00:52:09
and doing a layout in Emco simulation so
00:52:12
that's all for this video hope you
00:52:14
thoroughly enjoyed the content presented
00:52:16
in this tutorial and I look forward to
00:52:18
see you in part two of this tutorial
00:52:21
series have a great time designing and
00:52:24
wish you all the best in your design
00:52:26
work my friends

الوسوم

amplificador de potência
design de RF
GaN
eficiência
linearidade
modelo não linear
análise de carga
DPD
classes de operação
tutorial de design