Post by: b^3 on October 08, 2011, 05:20:48 pm
Ok guys and girls, this is a guide/reference for using the Ti-nspire for Specialist Maths. It will cover the simplest of things to a few tricks. This guide has been written for Version 3.1.0.392. To update go to http://education.ti.com/calculators/downloads/US/Software/Detail?id=6767
Any additions or better methods are welcomed. Also let me know if you spot any mistakes.
Guide to Using the Ti-nspire for METHODS - The simple and the overcomplicated: http://www.atarnotes.com/forum/index.php?topic=125386.msg466347#msg466347
Printer Friendly PDF version: http://www.atarnotes.com/?p=notes&a=feedback&id=661
NOTE: There is a mistake in the printable version. Under the shortcut keys the highlighting should read "Copy: Ctrl left or right to highlight, [SHIFT (the one with CAPS on it)] + [c]"
Simple things will have green headings, complicated things and tricks will be in red. Firstly some simple things. Also Note that for some questions, to obtain full marks you will need to know how to do this by hand. DONT entirely rely on the calculator. Remember this should help speed through those Multiple Choice and to double check your answers for Extended Respons quickly.
Solve, Factor & Expand
These are the basic functions you will need to know.
Open Calculate (A)
Solve: [Menu] [3] [1] (equation, variable)|Domain
Factor: [Menu] [3] [2] (terms)
Expand: [Menu] [3] [3] (terms)
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen041.jpg)
Vectors
These way the Ti-nspire handles vectors is to set them up like a 1 X 3 matrix. E.g. The vector 2i+2j+1k would be represented by the matrix
Its easier to work with the vectors if you define them. E.g. [Menu] [1] [1] a =
The functions that can be applied to the vectors are:
Unit Vector: [Menu] [7] [C] [1] - unitV(
Dot Product: [Menu] [7] [C] [3] dotP(
Magnitude: type "norm()" norm(
E.g. a=2i+2j+k, b=6i+2j-16k, Find the Unit vector of a and a.b
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen053.jpg)
E.g. a and b are perpendicular
Graphing Vectors Equations
Normally expresses as a function of t. Graphed as parametric equations. Select the graph entry bar, [ctrl] + [Menu] [2:Graph Type] [2:Parametric]
Enter in the i coefficient as x1(t) and the j coefficient as x2(t)
e.g. Graph
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen035.jpg)
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen036.jpg)
Complex Numbers
There are two important functions related to complex numbers. They work the same as the original functions, but will give complex solutions aswell.
cSolve: [Menu] [3] [C] [1]
cFactor: [Menu] [3] [C] [1]
E.g. Solve
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen037.jpg)
Quicker Cis(θ) Evaluations
1. Define ([Menu] [1] [1]) cis(θ)=\cos(θ)+i\sin(θ)
2. Simply plug in the value of theta
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen038.jpg)
Finding Arguments
1. Use the angle function (i.e. find it in the catalogue of type angle(*)
E.g. Find the Argument of
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen039.jpg)
Defining Domains
While graphing or solving, domains can be defined by the addition of |lowerbound<x<upperbound
The less than or equal to and greater than or equal to signs can be obtained by pressing ctrl + < or >
e.g. Graph
Enter
(http://i55.tinypic.com/2vbrjua.jpg)
This is particulary useful for fog and gof functions, when a domain is restriced, the resulting functions domain will also be restricted.
E.g. Find the equation of
1. Define the two equations in the Calulate page. [Menu] [1] [1]
(http://i56.tinypic.com/2vlji8y.jpg)
2. Open a graph page and type, f(g(x)) into the graph bar
(http://i53.tinypic.com/i42sl5.jpg)
The trace feature can be used to find out the range and domain. Trace: [Menu] [5] [1]
Here
Completing the Square
The easy way to find the turning point quickly. The Ti-nspire has a built in function for completing the square.
[Menu] [3] [5] - (function,variable)
e.g. Find the turning point of
(http://i56.tinypic.com/2lduemw.jpg)
So from that the turning point will be at (-2,1)
Easy Maximum and Minimums
In the newer version of the Ti-nspire OS, there are functions to find maximum, minimums, tangent lines and normal lines with a couple of clicks, good for multiple choice, otherwise working would need to be shown. You can do some of these visually on the graphing screen or algebraically in the calculate window.
Maximums: [Menu] [4] [7] (terms, variable)|domain
Minimums: [Menu] [4] [8] (terms, variable)|domain
E.g. Find the values of x for which
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen031.jpg)
Tangents at a point: [Menu] [4] [9] (terms, variable, point)
Normals at a point: [Menu] [4] [A] - (terms, variable, point)
E.g. Find the equation of the tangent and the normal to the curve
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen032.jpg)
Visualisation of Addition of Ordinates
Graph f(x) and g(x), then graph f(x)+g(x)
E.g. Graph
Then
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen042.jpg)
Finding Vertical Asymptotes
Vertical Asymptotes occur when the function is undefined at a given value of x, i.e. when anything is divided by 0. We can manipulate this fact to find vertical asymptotes by letting the function equal
e.g. Find the vertical asymptotes for
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen040.jpg)
So for
Dont forget to find those other non-vertical asymptotes too.
The x-y Function Test
Every now and then you will come across this kind of question in a multiple choice section.
If
A.
B.
C.
D.
E.
You could do it by hand or do it by calculator. The easiest way is to define the functions and solve the condition for x, then test whether the option is true. If true is given, it is true otherwise it is false.
(http://i56.tinypic.com/1zf4j02.jpg)
So option B is correct.
The Time Saver for Derivatives
By defining, f(x) and then defining df(x)= the derivative, you wont have to continually type in the derivative keys and function. It also allows you to plug in values easily into f(x) and f(x).
Derivative: [Menu] [4] [1]
E.g. Find the derivative of
Define f(x), then define df(x)
(http://i56.tinypic.com/2igy549.jpg)
The same thing can be done for the double derivative.
(http://i55.tinypic.com/14llxqc.jpg)
Just remember to redefine the equations or use a different letter, e.g. g(x) and dg(x)
Implicit Differentiation
[Menu] [4] [E] impDif(equation, variable 1, variable 2)
E.g. Differentiate
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen043.jpg)
Solving For Coefficients Using Definitions of Functions
Instead of typing out big long strings of equations and forgetting which one is the antiderivative and which one is the original, defined equations can be used to easily and quickly solve for the coefficients.
E.g. An equation of the form
1. Define
2. Define the derivative of the f(x) i.e. df(x)
3. Use solve function and substitute values in, solve for a, b, c & d.
(http://i52.tinypic.com/23v1e2w.jpg)(http://i56.tinypic.com/2z5n6g4.jpg)
So
Deriving Using the Right Mode
The derivative of circular functions are different for radians and degrees. Remember to convert degrees to radians and be in radian mode, as the usual derivatives that you learn e.g.
RADIAN MODE DEGREES MODE
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen019.jpg)(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen020.jpg)
Getting Exact Values On the Graph Screen
Now for what you have all been dreaming of. Exact values on the graphing screen. Now the way to do this is a little bit annoying.
1. Open up a graph window
2. Plot a function e.g.
3. Trace the graph using [Menu] [5] [1]
4. Trace right till you hit around 0.9 or 1.2 and click the middle button to plot the point.
5. Press ESC
6. Move the mouse over the x-value and click so that it highlights, then move it slightly to the right and click again. Clear the value and enter in
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen021.jpg).
Using tCollect to simplify awkward expressions
Sometimes the calculator wont simplify something the way we want it to. tCollect simplifies expressions that involves trigonometric powers higher than 1 or lower than -1 to linear trigonometric expressions.
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen022.jpg)
Differntial Equation Solver
[Menu] [4] [D] DeSolve(equation, variable on bottom, variable on top)
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen045.jpg)
Integrals
[Menu] [4] [3]
E.g. If find
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen044.jpg)
Plotting Differential Equations + Slope Fields
Firstly you will need to open a graphing screen.
Then you need to setup up the mode for differential equations. This can be done in two ways:
A. Select the graph entry bar and press [Ctrl] [Menu] then select [2] (Graph Type) [6] (Differential Equation)
or
B. [Menu] [3] [6]
Now the interface comes up.
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen046.jpg)
NOTE 1: When entering y in the bar, you will have to enter y1.
NOTE 2: If you want to plot a second differential equation that is not related to the first, you will need to either, open a new document (not just a graphing screen, for some reason the original equation that you plotted will be shown again) or clear out all the differential equations in the graph entry bar (i.e. y1, y2...) or open a new problem in the current document by pressing [Ctrl] [Home] [4] [1] [2]
e.g. Sketch the slope field
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen049.jpg)(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen050.jpg)
e.g. Sketch the slope field of
NOTE: Make sure you use y1
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen051.jpg)(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen052.jpg)
You will only need to draw the lines in the red box since
e.g. Sketch the slope field for
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen047.jpg)(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen048.jpg)
Dont forget a slope field should have a table of values with it.
Graphing Circles, Elipses, Hyperbolas in 1.5 easy steps
This allows you to plot equations in their zero form easily without having to rearrange for y and forming two (or more) equations.
Step 0: Firstly what you have to is rearrange the equation so that it equals 0.
e.g.
Now remove the
Step 1: Enter in the graph bar zeros(equation, dependent variable)
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen055.jpg)(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen054.jpg)
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen056.jpg)
Shortcut Keys
Copy: Ctrl left or right to highlight, [SHIFT (the one with CAPS on it)] + [c]
Paste: [Ctrl] + [v]
Insert Derivative: [CAPS] + ["-"]
Insert Integral: [CAPS] + ["+"]
∞: [Ctrl] + [i]
Thanks to Jane1234 & duquesne9995 for the shortcut keys. Thanks to vgardiy for the real easy sketching of equations in their zero form.
Remember you can always do other funs things like 3-D graphs. Enjoy. Yey 800th post.
(http://i1082.photobucket.com/albums/j373/mclaren200800/t11.jpg)(http://i1082.photobucket.com/albums/j373/mclaren200800/t12.jpg)
(http://i1082.photobucket.com/albums/j373/mclaren200800/t11-1.png)(http://i1082.photobucket.com/albums/j373/mclaren200800/t13.jpg)
Post by: tony3272 on October 08, 2011, 05:27:18 pm
Also if you want to do stuff with complex numbers on you cas you can also go:
Post by: Lasercookie on October 08, 2011, 05:34:13 pm
Post by: b^3 on October 08, 2011, 05:37:30 pm
Great job :PYeh once you defined it to be cos(x)+isin(x) it automatically simplfies it to that untill you start pluging numbers in. I'm just trying to fix up all the links now.
Also if you want to do stuff with complex numbers on you cas you can also go:, as the calc doesn't have a cis function.
Post by: b^3 on October 08, 2011, 06:08:49 pm
Post by: vea on October 08, 2011, 06:53:00 pm
Post by: HCbigstick on October 08, 2011, 07:01:14 pm
Post by: SamiJ on October 08, 2011, 07:14:01 pm
(http://i1082.photobucket.com/albums/j373/mclaren200800/t11.jpg)(http://i1082.photobucket.com/albums/j373/mclaren200800/t12.jpg)These are wicked! 8) :o ;D :D ;) :) ::) :)) Do you need the new software to do them?
(http://i1082.photobucket.com/albums/j373/mclaren200800/t11-1.png)(http://i1082.photobucket.com/albums/j373/mclaren200800/t13.jpg)
Post by: b^3 on October 08, 2011, 07:17:45 pm
As far as I know, you need the newer version to do it with, but there are all these new functions here and three that make checking you asnwers easier and quicker, so it's a good ide to upgrade. They got rid of a lot of the bugs too. If you do upgrade, when you are on the graphing window press menu, then 2:view, then 3: 3d graphing.(http://i1082.photobucket.com/albums/j373/mclaren200800/t11.jpg)(http://i1082.photobucket.com/albums/j373/mclaren200800/t12.jpg)These are wicked! 8) :o ;D :D ;) :) ::) :)) Do you need the new software to do them?
(http://i1082.photobucket.com/albums/j373/mclaren200800/t11-1.png)(http://i1082.photobucket.com/albums/j373/mclaren200800/t13.jpg)
Post by: jane1234 on October 08, 2011, 07:26:41 pm
Do you know if there is any way to use the 3D graphs to somehow plot vectors with i,j & k? For example, showing what i + 2j - 3k would look like? I was trying to figure this out hmm...
Post by: b^3 on October 08, 2011, 07:33:28 pm
Wow thanks, never knew the expand tool gave you partial fractions. :)Yeh it makes life easier. And WOW I just worked out how to rotate the 3d-graphs.
Do you know if there is any way to use the 3D graphs to somehow plot vectors with i,j & k? For example, showing what i + 2j - 3k would look like? I was trying to figure this out hmm...I don't think it can but I'll have a look around and post back if I figure anything out.
Post by: SamiJ on October 08, 2011, 07:35:41 pm
And WOW I just worked out how to rotate the 3d-graphs.This is crazy! :o :o :o
Post by: jane1234 on October 08, 2011, 07:36:49 pm
Wow thanks, never knew the expand tool gave you partial fractions. :)Yeh it makes life easier. And WOW I just worked out how to rotate the 3d-graphs.Do you know if there is any way to use the 3D graphs to somehow plot vectors with i,j & k? For example, showing what i + 2j - 3k would look like? I was trying to figure this out hmm...I don't think it can but I'll have a look around and post back if I figure anything out.
Haha have you clicked auto rotation yet? It'll spin around on its own... I think this could potentially amuse some people for hours...
Post by: b^3 on October 08, 2011, 07:38:41 pm
I have now and woow, there goes the rest of my holidays.Wow thanks, never knew the expand tool gave you partial fractions. :)Yeh it makes life easier. And WOW I just worked out how to rotate the 3d-graphs.Do you know if there is any way to use the 3D graphs to somehow plot vectors with i,j & k? For example, showing what i + 2j - 3k would look like? I was trying to figure this out hmm...I don't think it can but I'll have a look around and post back if I figure anything out.
Haha have you clicked auto rotation yet? It'll spin around on its own... I think this could potentially amuse some people for hours...
Post by: b^3 on October 08, 2011, 07:45:32 pm
Type Norm([1 3 4]) e.t.c.
I'll probably add it to the post here later, but won't be able to add it to the notes pdf doc.
Post by: b^3 on October 08, 2011, 07:57:05 pm
Wow thanks, never knew the expand tool gave you partial fractions. :)I don't think it is possible. I found how to do 2-d vectors, but it takes a lot of time, but good to check say you vectors for a parallelogram e.t.c
Do you know if there is any way to use the 3D graphs to somehow plot vectors with i,j & k? For example, showing what i + 2j - 3k would look like? I was trying to figure this out hmm...
http://education.ti.com/calculators/downloads/US/Activities/Detail?id=12401
Post by: jane1234 on October 08, 2011, 08:06:43 pm
Wow thanks, never knew the expand tool gave you partial fractions. :)I don't think it is possible. I found how to do 2-d vectors, but it takes a lot of time, but good to check say you vectors for a parallelogram e.t.c
Do you know if there is any way to use the 3D graphs to somehow plot vectors with i,j & k? For example, showing what i + 2j - 3k would look like? I was trying to figure this out hmm...
http://education.ti.com/calculators/downloads/US/Activities/Detail?id=12401
Ah okay - they'll probably include it in a later version when we've all finished... :P
Post by: b^3 on October 08, 2011, 08:34:00 pm
Post by: b^3 on October 09, 2011, 09:35:24 am
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen055.jpg)(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen054.jpg)
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen056.jpg)
NEW Printer Friendly PDF Version 2.00: http://www.atarnotes.com/?p=notes&a=feedback&id=661
Post by: pi on October 09, 2011, 12:40:43 pm
Post by: b^3 on October 09, 2011, 01:02:50 pm
^^Did not know that one! Good tip! :)Yeh I didn't either until vgardiy pointed it out in the methods thread. Does make life easier doesn't it.
Moderator action: removed real name, sorry for the inconvenience
Post by: Lord of Tzeentch on November 01, 2011, 04:51:11 pm
Post by: b^3 on November 01, 2011, 05:15:53 pm
Thanks for this, extremely useful! :)No problem, and if anyone else finds anything useful let me know. (Plus I probably should have added the finding the inverse function thing).
Post by: jinny1 on November 05, 2011, 02:30:09 pm
Post by: Vadermort on November 09, 2011, 08:46:50 pm
Post by: Lasercookie on November 09, 2011, 08:49:40 pm
I should probably add that to highlight text, you use CAPS left/right, not ctrl. Otherwise, great work! ;)Ah, thanks for that. I was confused as to why I couldn't highlight text after upgrading the OS. I was trying to figure out how to do it for ages haha.
Post by: b^3 on November 09, 2011, 08:51:20 pm
I should probably add that to highlight text, you use CAPS left/right, not ctrl. Otherwise, great work! ;)
NVM: Found it, sorry guys, the buttons are close. I'll fix it in the post and make a note to fix that in the prinatble version.
Post by: xkcirtap on November 10, 2011, 05:01:42 pm
Post by: b^3 on November 10, 2011, 05:09:26 pm
in x(t) you should have 2/(t-1)
in y(t) you should have 4/(t+3)
underneath that you need to cahnge the 6.28 to a 5.
It draws a horizontal line at y=1, which is an asymptote (I had to check it manually).
I;m not 100% sure if the t>5 rstriction worked though.
For this one I think it is better to do it manually so that you don't encount any errors as a result as the calc. sorry I can't really help.
Post by: xkcirtap on November 10, 2011, 05:16:42 pm
Post by: tiktokcheekaboom on November 10, 2011, 10:43:33 pm
I remember someone telling me once that you should be able to get specific points (with decimal places and all) from a graph by somehow linking the graph to a spreadsheets page, but how exactly do you do that? I'm just worried that I may end up using an extremely inaccurate value from the graphing screen in section two :S
Really appreciate any help or advice! Thanks in advance :D
Post by: daliu on November 12, 2011, 08:37:48 am
Post by: b^3 on November 12, 2011, 09:12:25 am
Hey b^3, this helped a ton yesterday in the tech active Exam 2. I ended up using a ton of stuff from this guide that I otherwise wouldn't have (graphing slope field equations, for example) so seriously, thanks heaps :DNo problem guys :) Hope you all did well.
Post by: jadams on May 04, 2012, 05:48:57 pm
Post by: DisaFear on May 04, 2012, 05:52:59 pm
Post by: b^3 on May 04, 2012, 05:56:16 pm
Post by: theya on July 15, 2015, 06:44:24 pm
though just a suggestion here. the ti nspire already has capabilities of handling polar form without defining your own function for cis
read here:
https://epsstore.ti.com/OA_HTML/csksxvm.jsp?nSetId=120079
Post by: SmartWorker on December 17, 2019, 01:18:55 pm
Version 2.00
Ok guys and girls, this is a guide/reference for using the Ti-nspire for Specialist Maths. It will cover the simplest of things to a few tricks. This guide has been written for Version 3.1.0.392. To update go to http://education.ti.com/calculators/downloads/US/Software/Detail?id=6767
Any additions or better methods are welcomed. Also let me know if you spot any mistakes.
Guide to Using the Ti-nspire for METHODS - The simple and the overcomplicated: http://www.atarnotes.com/forum/index.php?topic=125386.msg466347#msg466347
Printer Friendly PDF version: http://www.atarnotes.com/?p=notes&a=feedback&id=661
NOTE: There is a mistake in the printable version. Under the shortcut keys the highlighting should read "Copy: Ctrl left or right to highlight, [SHIFT (the one with CAPS on it)] + [c]"
Simple things will have green headings, complicated things and tricks will be in red. Firstly some simple things. Also Note that for some questions, to obtain full marks you will need to know how to do this by hand. DONT entirely rely on the calculator. Remember this should help speed through those Multiple Choice and to double check your answers for Extended Respons quickly.
Solve, Factor & Expand
These are the basic functions you will need to know.
Open Calculate (A)
Solve: [Menu] [3] [1] (equation, variable)|Domain
Factor: [Menu] [3] [2] (terms)
Expand: [Menu] [3] [3] (terms)
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen041.jpg)
Vectors
These way the Ti-nspire handles vectors is to set them up like a 1 X 3 matrix. E.g. The vector 2i+2j+1k would be represented by the matrixYou can enter a matrix by pressing [ctrl] + ["x"], then select the 3 X 3 matrix and enter in the appropriate dimensions.
Its easier to work with the vectors if you define them. E.g. [Menu] [1] [1] a =
The functions that can be applied to the vectors are:
Unit Vector: [Menu] [7] [C] [1] - unitV()
Dot Product: [Menu] [7] [C] [3] dotP(,
Magnitude: type "norm()" norm(
E.g. a=2i+2j+k, b=6i+2j-16k, Find the Unit vector of a and a.b
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen053.jpg)
E.g. a and b are perpendicular
Graphing Vectors Equations
Normally expresses as a function of t. Graphed as parametric equations. Select the graph entry bar, [ctrl] + [Menu] [2:Graph Type] [2:Parametric]
Enter in the i coefficient as x1(t) and the j coefficient as x2(t)
e.g. Graph
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen035.jpg)
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen036.jpg)
Complex Numbers
There are two important functions related to complex numbers. They work the same as the original functions, but will give complex solutions aswell.
cSolve: [Menu] [3] [C] [1]
cFactor: [Menu] [3] [C] [1]
E.g. Solvefor z and factorise
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen037.jpg)
Quicker Cis(θ) Evaluations
1. Define ([Menu] [1] [1]) cis(θ)=\cos(θ)+i\sin(θ)
2. Simply plug in the value of theta
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen038.jpg)
Finding Arguments
1. Use the angle function (i.e. find it in the catalogue of type angle(*)
E.g. Find the Argument of
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen039.jpg)
Defining Domains
While graphing or solving, domains can be defined by the addition of |lowerbound<x<upperbound
The less than or equal to and greater than or equal to signs can be obtained by pressing ctrl + < or >
e.g. Graphfor
Enterinto the graphs bar
(http://i55.tinypic.com/2vbrjua.jpg)
This is particulary useful for fog and gof functions, when a domain is restriced, the resulting functions domain will also be restricted.
E.g. Find the equation ofwhen
and
1. Define the two equations in the Calulate page. [Menu] [1] [1]
(http://i56.tinypic.com/2vlji8y.jpg)
2. Open a graph page and type, f(g(x)) into the graph bar
(http://i53.tinypic.com/i42sl5.jpg)
The trace feature can be used to find out the range and domain. Trace: [Menu] [5] [1]
Herewhere the Domain = (-1.5,1] and Range =[0,4)
Completing the Square
The easy way to find the turning point quickly. The Ti-nspire has a built in function for completing the square.
[Menu] [3] [5] - (function,variable)
e.g. Find the turning point of
(http://i56.tinypic.com/2lduemw.jpg)
So from that the turning point will be at (-2,1)
Easy Maximum and Minimums
In the newer version of the Ti-nspire OS, there are functions to find maximum, minimums, tangent lines and normal lines with a couple of clicks, good for multiple choice, otherwise working would need to be shown. You can do some of these visually on the graphing screen or algebraically in the calculate window.
Maximums: [Menu] [4] [7] (terms, variable)|domain
Minimums: [Menu] [4] [8] (terms, variable)|domain
E.g. Find the values of x for whichhas a maxmimum and a minimum for
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen031.jpg)
Tangents at a point: [Menu] [4] [9] (terms, variable, point)
Normals at a point: [Menu] [4] [A] - (terms, variable, point)
E.g. Find the equation of the tangent and the normal to the curvewhen
.
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen032.jpg)
Visualisation of Addition of Ordinates
Graph f(x) and g(x), then graph f(x)+g(x)
E.g. Graph
Then
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen042.jpg)
Finding Vertical Asymptotes
Vertical Asymptotes occur when the function is undefined at a given value of x, i.e. when anything is divided by 0. We can manipulate this fact to find vertical asymptotes by letting the function equaland solving for x.
e.g. Find the vertical asymptotes for
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen040.jpg)
So forthere is a vertical asymptotes at
and
Dont forget to find those other non-vertical asymptotes too.
The x-y Function Test
Every now and then you will come across this kind of question in a multiple choice section.
If, which of the following is true?
A.
B.
C.
D.
E.
You could do it by hand or do it by calculator. The easiest way is to define the functions and solve the condition for x, then test whether the option is true. If true is given, it is true otherwise it is false.
(http://i56.tinypic.com/1zf4j02.jpg)
So option B is correct.
The Time Saver for Derivatives
By defining, f(x) and then defining df(x)= the derivative, you wont have to continually type in the derivative keys and function. It also allows you to plug in values easily into f(x) and f(x).
Derivative: [Menu] [4] [1]
E.g. Find the derivative of
Define f(x), then define df(x)
(http://i56.tinypic.com/2igy549.jpg)
The same thing can be done for the double derivative.
(http://i55.tinypic.com/14llxqc.jpg)
Just remember to redefine the equations or use a different letter, e.g. g(x) and dg(x)
Implicit Differentiation
[Menu] [4] [E] impDif(equation, variable 1, variable 2)
E.g. Differentiatewith respect to x.
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen043.jpg)
Solving For Coefficients Using Definitions of Functions
Instead of typing out big long strings of equations and forgetting which one is the antiderivative and which one is the original, defined equations can be used to easily and quickly solve for the coefficients.
E.g. An equation of the formcuts the x-axis at (-2,0) and (2,0). It cuts the y-axis at (0,1) and has a local maximum when
. Find the values of a, b, c & d.
1. Define(Make sure you put a multiplication sign between the letters)
2. Define the derivative of the f(x) i.e. df(x)
3. Use solve function and substitute values in, solve for a, b, c & d.
(http://i52.tinypic.com/23v1e2w.jpg)(http://i56.tinypic.com/2z5n6g4.jpg)
Soand
and the equation of the curve is
Deriving Using the Right Mode
The derivative of circular functions are different for radians and degrees. Remember to convert degrees to radians and be in radian mode, as the usual derivatives that you learn e.g.are in radians NOT degrees.
RADIAN MODE DEGREES MODE
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen019.jpg)(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen020.jpg)
Getting Exact Values On the Graph Screen
Now for what you have all been dreaming of. Exact values on the graphing screen. Now the way to do this is a little bit annoying.
1. Open up a graph window
2. Plot a function e.g.
3. Trace the graph using [Menu] [5] [1]
4. Trace right till you hit around 0.9 or 1.2 and click the middle button to plot the point.
5. Press ESC
6. Move the mouse over the x-value and click so that it highlights, then move it slightly to the right and click again. Clear the value and enter in
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen021.jpg).
Using tCollect to simplify awkward expressions
Sometimes the calculator wont simplify something the way we want it to. tCollect simplifies expressions that involves trigonometric powers higher than 1 or lower than -1 to linear trigonometric expressions.
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen022.jpg)
Differntial Equation Solver
[Menu] [4] [D] DeSolve(equation, variable on bottom, variable on top)
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen045.jpg)
Integrals
[Menu] [4] [3]
E.g. If findif
and y=0 when x=0
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen044.jpg)
Plotting Differential Equations + Slope Fields
Firstly you will need to open a graphing screen.
Then you need to setup up the mode for differential equations. This can be done in two ways:
A. Select the graph entry bar and press [Ctrl] [Menu] then select [2] (Graph Type) [6] (Differential Equation)
or
B. [Menu] [3] [6]
Now the interface comes up.
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen046.jpg)
NOTE 1: When entering y in the bar, you will have to enter y1.
NOTE 2: If you want to plot a second differential equation that is not related to the first, you will need to either, open a new document (not just a graphing screen, for some reason the original equation that you plotted will be shown again) or clear out all the differential equations in the graph entry bar (i.e. y1, y2...) or open a new problem in the current document by pressing [Ctrl] [Home] [4] [1] [2]
e.g. Sketch the slope field
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen049.jpg)(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen050.jpg)
e.g. Sketch the slope field offor
NOTE: Make sure you use y1
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen051.jpg)(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen052.jpg)
You will only need to draw the lines in the red box sinceif you draw the unrequited lines you may lose marks
e.g. Sketch the slope field forwith initial conditions x=1 when y=0
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen047.jpg)(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen048.jpg)
Dont forget a slope field should have a table of values with it.
Graphing Circles, Elipses, Hyperbolas in 1.5 easy steps
This allows you to plot equations in their zero form easily without having to rearrange for y and forming two (or more) equations.
Step 0: Firstly what you have to is rearrange the equation so that it equals 0.
e.g.becomes
becomes
becomes
Now remove thepart
Step 1: Enter in the graph bar zeros(equation, dependent variable)
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen055.jpg)(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen054.jpg)
(http://i1082.photobucket.com/albums/j373/mclaren200800/Screen056.jpg)
Shortcut Keys
Copy: Ctrl left or right to highlight, [SHIFT (the one with CAPS on it)] + [c]
Paste: [Ctrl] + [v]
Insert Derivative: [CAPS] + ["-"]
Insert Integral: [CAPS] + ["+"]
∞: [Ctrl] + [i]
Thanks to Jane1234 & duquesne9995 for the shortcut keys. Thanks to vgardiy for the real easy sketching of equations in their zero form.
Remember you can always do other funs things like 3-D graphs. Enjoy. Yey 800th post.
(http://i1082.photobucket.com/albums/j373/mclaren200800/t11.jpg)(http://i1082.photobucket.com/albums/j373/mclaren200800/t12.jpg)
(http://i1082.photobucket.com/albums/j373/mclaren200800/t11-1.png)(http://i1082.photobucket.com/albums/j373/mclaren200800/t13.jpg)
Hi,
Is there a current guide for the Ti-nspire CX CAS for methods and specialist for version 4.5.0.1180. The images are blurred for this guide.
Thanks