Transforming an equation into a first-order system – Texas Instruments TI-86 User Manual

140

Chapter 10: Differential Equation Graphing

10DIFFEQ.DOC TI-86, Chap 10, US English Bob Fedorisko Revised: 02/13/01 2:28 PM Printed: 02/13/01 3:02 PM Page 140 of 20

10DIFFEQ.DOC TI-86, Chap 10, US English Bob Fedorisko Revised: 02/13/01 2:28 PM Printed: 02/13/01 3:02 PM Page 140 of 20

10DIFFEQ.DOC TI-86, Chap 10, US English Bob Fedorisko Revised: 02/13/01 2:28 PM Printed: 02/13/01 3:02 PM Page 140 of 20

ᕥ Display the axes editor and enter the

equation variable for which you want to
solve. (Do not set

y=Q

.)

ᕦ Accept or change

fldRes

(resolution).

) &

1

ᕧ Display the graph. With the default

window variable values set, the slope
fields for this graph are not very
illustrative.

- i

ᕨ Change the window variables

xMin

,

xMax

,

yMin

, and

yMax

.

ᕩ Select

TRACE

from the

GRAPH

menu to re-

plot the graph and activate the trace cursor.
Trace the solution. The trace cursor
coordinates for

t

and

Q1

are displayed.

' # # # #

0

#

5

# #

0

#

20

/ )

" and !

Transforming an Equation into a First-Order System

On the TI

-86, to enter a second-order or higher (up to ninth-order) differential equation, you

must transform it to a system of first-order differential equations. For example, to enter the
second-order differential equation y''=

L

y, you must transform it to two first-order

differential equations, as shown in the chart below.

Differentiate...

Define the variables as...

And then substitute:

Q'1

=y'

Q1

=y

Q'1=Q2

(since

Q'1

=y'=

Q2

)

Q'2

=y''

Q2

=y'

Q'2=

L

Q1

In SlpFld field format, x=t is
always true; y=Q1 and
fldRes=15

are the default

axes settings.