File r36/LESS3 artifact 3be3efe186 part of check-in fe6b5d0560


COMMENT
                 REDUCE INTERACTIVE LESSON NUMBER 3

                         David R. Stoutemyer
                        University of Hawaii

                     Update for REDUCE 3.4 
                         Herbert Melenk
                      Konrad-Zuse-Zentrum Berlin

COMMENT This is lesson 3 of 7 REDUCE lessons.  Please refrain from
using variables beginning with the letters F through H during the
lesson.

Mathematics is replete with many named elementary and not-so-
elementary functions besides the set built into REDUCE such as SIN,
COS, and LOG, and it is often convenient to utilize expressions
containing a functional form such as f(x) to denote an unknown
function or a class of functions. Functions are called operators in
REDUCE, and by merely declaring their names as such, we are free to
use them for functional forms. For example;

OPERATOR F;
G1 := F(F(COT(F)), F());

COMMENT  Note that
   1.  We can use the same name for both a variable and an operator.
       (However, this practice often leads to confusion.)
   2.  We can use the same operator for any number of arguments --
       including zero arguments such as for F().
   3.  We can assign values to specific instances of functional
       forms;

PAUSE;
COMMENT COT is one of the functions already defined in REDUCE
together with a few of its properties. However, the user can augment
or even override these definitions depending on the needs of a given
problem. For example, if one wished to write COT(F) in terms of TAN,
one could say;

COT(F) := 1/TAN(F);
G1 := G1 + COT(H+1);

PAUSE;

COMMENT  Naturally, our assignment for COT(F) did not affect
COT(H+1) in our example above. However, we can use a LET rule to
make all cotangents automatically be replaced by the reciprocal of
the corresponding tangents:;

LET COT(~F) => 1/TAN(F);
G1;

COMMENT Any variable preceded by a tilde is a dummy variable which
is distinct from any other previously or subsequently introduced
indeterminate, variable, or dummy variable having the same name
outside the rule. The leftmost occurrence of a dummy variable in
a rule must be marked with a tilde. 

The arguments to LET are either single rules or lists (explicitly 
enlosed in {..} or as a variable with a list value). All elements 
of a list have to be rules (i.e., expressions written in terms of
the operator "=>") or names of other rule lists. So alternatively
we could have written the above command as
      LET COT(~F) => 1/TAN(F) 
   or as command sequence
      RS:={COT(~F) => 1/TAN(F)}
      LET RS

The CLEARRULES command allows to clear one or more rules. They
have to be entered here in the same form as for LET - otherwise
REDUCE is unable to identify them.

CLEARRULES COT(~F) => 1/TAN(F);
COT(G+5);
 
COMMENT alternative forms would have been
     CLEARRULES {COT(~F) => 1/TAN(F)}
   or with the above value of RS
     CLEARRULES RS
Note, that a call CLEAR RS would not remove the rule(s) from
the system - it only would remove the list value from the variable
RS;

PAUSE;

COMMENT The arguments of a functional form on the left-hand side of a
rule can be more complicated than mere indeterminates.  For example,
we may wish to inform REDUCE how to differentiate expressions involving
a symbolic function P, whose derivative is expressed in terms of
another function Q;

OPERATOR P,Q;
LET DF(P(~X),X) => Q(X)**2;

DF(3*P(F*G), G);

COMMENT Also, REDUCE obviously knows the chain rule;

PAUSE;

COMMENT As another example, suppose that we wish to employ the
angle-sum identities for SIN and COS;

LET{SIN(~X+~Y) => SIN(X)*COS(Y) + SIN(Y)*COS(X),
    COS(~X+~Y) => COS(X)*COS(Y) - SIN(X)*SIN(Y)};
COS(5+F-G);

COMMENT  Note that:
   1.  LET can have any number of replacement rules written
       as a list.
   2.  There was no need for rules with 3 or more addends, because
       the above rules were automatically employed recursively, with
       two of the three addends 5, F, and -G grouped together as one
     of the dummy variables the first time through.
   3.  Despite the subexpression F-G in our example, there was no
       need to make rules for the difference of two angles, because
       subexpressions of the form X-Y are treated as X+(-Y).
   4.  Built-in rules were employed to convert expressions of the
       form SIN(-X) or COS(-X) to -SIN(X) or COS(X) respectively.

As an exercise, try to implement rules which transform the logarithms
of products and quotients respectively to sums and differences of
logarithms, while converting the logarithm of a power of a quantity to
the power times the logarithm of the quantity; PAUSE;

COMMENT  Actually, the left-hand side of a rule also can be
somewhat more general than a functional form.  The left-hand side can
be a power of an indeterminate or of a functional form, or the left-
hand side can be a product of such powers and/or indeterminates or
functional forms.  For example, we can have the rule 
"SIN(~X)**2=>1-COS(~X)**2", or we can have the rule;

LET COS(~X)**2 => 1 - SIN(~X)**2;
G1 := COS(F)**3 + COS(G);
PAUSE;

COMMENT Note that a replacement takes place wherever a left-hand side of
a rule divides a term.  With a rule replacing SIN(X)**2 and a rule
replacing COS(X)**2 simultaneously in effect, an expression which uses
either one will lead to an infinite recursion that eventually exhausts
the available storage. (Try it if you wish -- after the lesson).  We are
also permitted to employ a more symmetric rule using a top level "+"
provided that no free variables appear in the rule.  However, a rule
such as "SIN(~X)**2+COS(X)**2=>1" is not permitted.  We can
get around the restriction against a top-level "+" on the left side
though, at the minor nuisance of having to employ an operator whenever
we want the rule applied to an expression:;

CLEARRULES COS(~X)**2 => 1 - SIN(~X)**2;
OPERATOR TRIGSIMP;
TRIGSIMP_RULES:=
  {TRIGSIMP(~A*SIN(~X)**2 + A*COS(X)**2 + ~C) => A + TRIGSIMP(C),
   TRIGSIMP(~A*SIN(~X)**2 + A*COS(X)**2) => A,
   TRIGSIMP(SIN(~X)**2 + COS(X)**2 + ~C) => 1 + TRIGSIMP(C),
   TRIGSIMP(SIN(~X)**2 + COS(X)**2) => 1,
   TRIGSIMP(~X) => X}$
G1 := F*COS(G)**2 + F*SIN(G)**2 + G*SIN(G)**2 + G*COS(G)**2 + 5;
G1 := TRIGSIMP(G1) WHERE TRIGSIMP_RULES;
PAUSE;


COMMENT Here we use another syntactical paradigm: the rule list
is assigned to a name (here TRIGSIMP_RULES) and it is activated
only locally for one evaluation, using the WHERE clause.

Why doesn't our rule TRIGSIMP(~X)=>X defeat the other more
specific ones?  The reason is that rules inside a list are applied in a
first-in-first-applied order, with the whole process immediately
restarted whenever any rule succeeds.  Thus the rule TRIGSIMP(X)=X,
intended to make the operator TRIGSIMP eventually evaporate, is tried
only after all of the genuine simplification rules have done all that
they can. For such reasons we usually write rules for an operator in
an order which proceeds from the most specific to the most general
cases.  Experimentation will reveal that TRIGSIMP will not simplify
higher  powers of  sine  and  cosine, such  as  COS(X)**4  +
2*COS(X)**2*SIN(X)**2 + SIN(X)**4,  and that TRIGSIMP will not
necessarily work when there are more than 6 terms. This latter
restriction is not fundamental but is a practical one imposed to keep
the combinatorial searching associated with the current algorithm
under reasonable control. As an exercise, see if you can generalize
the rules sufficiently so that 5*COS(H)**2+6*SIN(H)**2 simplifies to
5 + SIN(H)**2 or to 6-COS(H)**2;

PAUSE;

COMMENT  rules do not need to have free variables. For
example, we could introduce  the simplification rule to replace all
subsequent instances of M*C**2 by ENERGY;

CLEAR M,C,ENERGY;
G1 := (3*M**2*C**2 + M*C**3 + C**2 + M + M*C + M1*C1**2)
              WHERE M*C**2 => ENERGY;
PAUSE;

COMMENT Suppose that instead we wish to replace M by ENERGY/C**2:;

G1 WHERE M=>ENERGY/C**2;

COMMENT You may wonder how a rule of the trivial form 
"indeterminate => ..." differs from the corresponding assignment 
"indeterminate := ...". The difference is

   1.  The rule does not replace any contained bound variables
       with their values until the rule is actually used for a
       replacement.
   2.  The LET rule performs the evaluation of any contained bound
       variables every time the rule is used.

Thus, the rule "X => X + 1" would cause infinite recursion at the
first subsequent occurrence of X, as would the pair of rules 
"{X=>Y, Y=>X}". (Try it! -- after the lesson.) To illustrate point 1
above, compare the following sequence with the analogous earlier one in
lesson 2 using assignments throughout;

CLEAR E1, F;
E2:= F;
LET  F1 => E1 + E2;
F1;
E2 := G;
F1;
PAUSE;

COMMENT For a subsequent example, we need to replace E**(I*X) by
COS(X)**2 + I*SIN(X)**2 for all X. See if you can successfully
introduce this rule;

PAUSE;
E**I;

COMMENT REDUCE does not match I as an instance of the pattern I*X
with X=1, so if you neglected to include a rule for this degenerate
case, do so now;

PAUSE;
CLEAR X, N, NMINUS1;
ZERO := E**(N*I*X) - E**(NMINUS1*I*X)*E**(I*X);
REALZERO := SUB(I=0, ZERO);
IMAGZERO := SUB(I=0, -I*ZERO);

COMMENT Regarding the last two assignments as equations, we can solve
them to get recurrence relations defining SIN(N*X) and COS(N*X) in
terms of angles having lower multiplicity.

Can you figure out why I didn't use N-1 rather than NMINUS1 above?

Can you devise a similar technique to derive the angle-sum identities
that we previously implemented?;

PAUSE;

COMMENT To implement a set of trigonometric multiple-angle expansion
rules, we need to match the patterns SIN(N*X) and COS(N*X) only when N
is an integer exceeding 1.  We can implement one of the necessary rules
as follows;

   COS(~N*~X) => COS(X)*COS((N-1)*X) - SIN(X)*SIN((N-1)*X)
             WHEN FIXP N AND N>1

COMMENT Note:
   1.  In a conditional rule, any dummy variables should
       appear in the lhs of the replacement with a tilde.
   2.  FIXP, standing for fix Predicate, is a built-in function
       which yields true if and only if its argument is an integer.
       In lesson 6 we will learn how to write such a function 
       exclusively for integers. Other useful predicates 
       are NUMBERP (it is true if its argument represents a
       numeric value, that is an integer, a rational number
       or a rounded (floating point) number) and EVENP
       (which is true if the argument is an integer multiple
       of 2).
   3.  Arbitrarily-complicated true-false conditions can be composed
       using the relational operators =, NEQ, <, >, <=, >=, together
       with the logical operators "AND", "OR", "NOT".
   4.  Operators < , >, <=, and >= work only when both sides are 
       numbers. 
   5.  The relational operators have higher precedence than "NOT",
       which has higher precedence than "AND", which has higher
       precedence than "OR".
   6.  In a sequence of items joined by "AND" operators, testing is
       done left to right, and testing is discontinued after the
       first item which is false.
   7.  In a sequence of items joined by "OR" operators, testing is
       done left to right, and testing is discontinued after the
       first item which is true.
   8.  We didn't actually need the "AND N>1" part in the above rule
       Can you guess why?

Your mission is to complete the set of multiple-angle rules and to
test them on the example COS(4*X) + COS(X/3) + COS(F*X);

PAUSE;

COMMENT Now suppose that we wish to write a set of rules for doing
symbolic  integration,  such  that  expressions  of  the  form
INTEGRATE(X**P,X) are replaced by X**(P+1)/(P+1) for arbitrary X and
P, provided P is independent of X. This will of course be less
complete that the analytic integration package available with REDUCE,
but for specific classes of integrals it is often a reasonable way to
do such integration. Noting that DF(P,X) is 0 if P is independent of
X, we can accomplish this as follows;

OPERATOR INTEGRATE;
LET INTEGRATE(~X**~P,X) => X**(P+1)/(P+1) WHEN DF(P,X)=0;
INTEGRATE(F**5,F);
INTEGRATE(G**G, G);
INTEGRATE(F**G,F);

PAUSE;

G1 := INTEGRATE(G*F**5,F) + INTEGRATE(F**5+F**G,F);

COMMENT The last example indicates that we must incorporate rules
which distribute integrals over sums and extract factors which are
independent of the second argument of INTEGRATE. Can you think of
rules which accomplish this? It is a good exercise, but this
particular pair of properties of INTEGRATE is so prevalent in
mathematics that operators with these properties are called linear,
and a corresponding declaration is built into REDUCE;

LINEAR INTEGRATE;
G1;
G1:= INTEGRATE(F+1,F) + INTEGRATE(1/F**5,F);

PAUSE;

COMMENT We overcame one difficulty and uncovered 3 others. Clearly
REDUCE does not regard F to match the pattern F**P as F**1, or 1 to
match the pattern as F**0, or 1/F**5 to match the pattern as F**(-1),
so we can add additional rules for such cases;

LET {
   INTEGRATE(1/~X**~P,X) => X**(1-P)/(1-P) WHEN DF(P,X)=0,
   INTEGRATE(~X,X) => X**2/2,
   INTEGRATE(1,~X) => X}$
G1;

COMMENT A remaining problem is that INTEGRATE(X**-1,X) will lead to
X**0/(-1+1), which simplifies to 1/0, which will cause a zero-divide
error message. Consequently, we should also include the correct rule
for this special case;

LET INTEGRATE(~X**-1,X) => LOG(X);
INTEGRATE(1/X,X);

PAUSE;
 
COMMENT We now collect the integration rules so far to one list
according to the law that within a rule set a more specific rule 
should precede the more general one;
 
INTEGRATE_RULES :=
{ INTEGRATE(1,~X) => X,
  INTEGRATE(~X,X) => X**2/2,
  INTEGRATE(~X**-1,X) => LOG(X),
  INTEGRATE(1/~X**~P,X) => X**(1-P)/(1-P) WHEN DF(P,X)=0,
  INTEGRATE(~X**~P,X) => X**(P+1)/(P+1) WHEN DF(P,X)=0}$

COMMENT This is the end of lesson 3.  We leave it as an intriguing
exercise to extend this integrator.

;END;


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