Trace: DM15L "Multi In Single Out" Solve

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public:calculator:guides:dm15l_miso_solve [06/08/22 07:23 BST] johnpublic:calculator:guides:dm15l_miso_solve [04/02/26 09:12 GMT] (current) – [Example : Nano-VNA TDR settings] john
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-====== DM15L "Miso" Solve ======+====== DM15L "Multi In Single Out" Solve ======
  
 ** Using multi-variable equations in SOLVE ** ** Using multi-variable equations in SOLVE **
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 <QUOTE> <QUOTE>
-<cite> +
-[[https://www.hpmuseum.org/cgi-sys/cgiwrap/hpmuseum/articles.cgi?read=556]] +
-</cite>+
  
 In order to conveniently employ SOLVE or INTEG on the HP-34C/15C/41C for multiple-input, single-output (MISO) user-defined functions, the user's program should emulate the way SOLVE and INTEG manage input variables on the three Pioneer-series models and the HP-33s. In order to conveniently employ SOLVE or INTEG on the HP-34C/15C/41C for multiple-input, single-output (MISO) user-defined functions, the user's program should emulate the way SOLVE and INTEG manage input variables on the three Pioneer-series models and the HP-33s.
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 This procedure utilizes indirect storage to make the RPN program more flexible. SOLVE and INTEG feed the each value of the floating variable as input to the user program, which immediately stores the value indirectly to its user-chosen register. Each variable in the function is then recalled for use in calculations, so the user program need not be structured to receive any particular variable from the stack. This procedure utilizes indirect storage to make the RPN program more flexible. SOLVE and INTEG feed the each value of the floating variable as input to the user program, which immediately stores the value indirectly to its user-chosen register. Each variable in the function is then recalled for use in calculations, so the user program need not be structured to receive any particular variable from the stack.
  
-</QUOTE>+
  
 <code> <code>
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 </code> </code>
 +
 +<cite>
 +[[https://www.hpmuseum.org/cgi-sys/cgiwrap/hpmuseum/articles.cgi?read=556]]
 +</cite>
 +
 +</QUOTE>
  
 ===== Example : OHMS LAW ===== ===== Example : OHMS LAW =====
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 from [[https://www.hpmuseum.org/forum/thread-1212.html]] from [[https://www.hpmuseum.org/forum/thread-1212.html]]
  
-<code>+<QUOTE> 
 + 
 So, can I write an equation in programming, such as So, can I write an equation in programming, such as
  
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 Code: Code:
-LBL A + 
-STO (i) +  LBL A 
-RCL 0 +  STO (i)  
-RCL* 1 +  RCL 0 
-RCL- 2 +  RCL* 1 
-RTN+  RCL- 2 
 +  RTN
  
 Example: Example:
-<I> STO 0 +  <I> STO 0 
-<E> STO 2 +  <E> STO 2 
-1 STO I +  1 STO I 
-SOLVE A+  SOLVE A 
 + 
 +<cite> from [[https://www.hpmuseum.org/forum/thread-1212.html]] </cite> 
 + 
 +</QUOTE> 
 + 
 +==== Example : Nano-VNA TDR settings ==== 
 + 
 +'' F = (Points^2 x v.f x 0.284 ) / distance '' 
 + 
 +  * Points -> R01 
 +  * Distance -> R02 
 +  * V.F -> R03 
 +  * Frequency -> R04 
 + 
 + 
 +<code> 
 + 
 +LBL 71 
 +Sto(i) 
 +RCL 01 
 +x^2 
 +RCL* 03 
 +0.284 
 +
 +RCL/ 02 
 +RCL- 04 
 +RTN
  
 </code> </code>
 +
 +=== Example ===
 +
 +Find the Frequency sweep width needed for a distance of 35m with the following settings:
 +
 +  * Distance = 35m
 +  * Points = 101
 +  * V.F = 0.66
 +
 +<code>
 +
 +101 STO01
 +35 STO02
 +.66 STO03
 +4 STO I
 +solve 71
 +
 +</code>
 +
 +Result = ''54.63MHz''
 +
  
  

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