HP 15c User Manual

Section 12: Calculating with Matrices 171

Keystrokes

Display

´> 2

A

4

4

Transforms A

P

into Ã.

´< C

A

4

4

Designates matrix C as
result matrix.

÷

C

4

1

Calculates X

P

and stores

in C.

|c

C

2

2

Transforms X

P

into X

C

.

lC

0.0372

Recalls c

11

.

lC

0.1311

Recalls c

12

.

lC

0.0437

Recalls c

21

.

lC

0.1543

Recalls c

22

.

´U

0.1543

Deactivates User mode.

´> 0

0.1543

Redimensions all matrices
to 0×0.

The currents, represented by the complex matrix X, can be derived from C

































i

i

I

I

2

1

0.1543

0.0437

0.1311

0.0372

X

Solving the matrix equation in the preceding example required 24 registers
of matrix memory – 16 for the 4×4 matrix A (which was originally entered
as a 4×2 matrix representing a 2×2 complex matrix), and four each for the
matrices B and C (each representing a 2×1 complex matrix). (However, you
would have used four fewer registers if the result matrix were matrix B.)
Note that since X and B are not restricted to be vectors (that is, single-
column matrices), X and B could have required more memory.

The HP-15C contains sufficient memory to solve, using the method
described above, the complex matrix equation AX = B with X and B having
up to six columns if A is 2×2, or up to two columns if A is 3×3.

*

(The

allowable number of columns doubles if the constant matrix B is used as the
result matrix.) If X and B have more columns, or if A is 4×4, you can solve
the equation using the alternate method below. This method differs from the
preceding one in that it involves separate inversion and multiplication
operations and fewer registers.

*

If all available memory space is dimensioned to the common pool (W: 1 64 0-0). Refer to appendix C,
Memory Allocation.