Chase.] ^bo [April 1.5, 



Harmonic Prediction. Calculation from Observation. 



i = 3.513 Node of subsidence, 3.513 



^ .703 Venus, mean perihelion, .698 



i .390 Mercury, .387 



tV -270 De LaRue, S. and L., .267 



tV -307 Kirk wood, .209 



tV -185 Gaillot, (Watson, II) .180 



ir .167 Gaillot & M., (Watson, I) .164 



^ .141 Chase, .140 



^V -131 VonOppolzer, .123 



I. The first of the six inner nodes, is r^^ = 22.84 Sun's semi-diameters, or 

 nearly = -^j Node of subsidence = .1065 Earth's semi-axis major. The 

 others are found as follows : 



11. 1 -=- 366.25653^ = .0195 Earth's semi-axis major. 



III. (9'' 55™ 26^5 -- 1 year)3 = .0109 



IV. 23 -r- 214.5 =.0074 " " 



V. (-^^ H- 214.5 =.0057 " " 



VI. 1h- 214.5 =.0047 



All of these nodes represent synchronous oscillations which are due to 

 mutual actions and reactions among the three important centres of nuclea- 

 tion (Sun), condensation (Earth), and nebulosity (Jupiter). While they 

 are all, unquestionably, radiodynamic, their simple dependence upon the 

 equality between Sun's nascent velocity and the velocity of light obviously 

 refers them to the photodynamic branch of radiodynamics. Can any good 

 reasons be given for regarding them as in any sense thermodynamic or 

 electrodynamic? 



The accordance of these six inner nodes of synchronism with the har- 

 monic nodes, is shown in the following table : 



Harmonic nodes. Synchronous nodes. 



34. Photodynamic Projection of Hydrogen. 

 The principles which are involved in Note 16 and in the first synchronous 

 node of the foregoing note, are further illustrated by the simple relations 

 which the molecular velocity of hydrogen bears to the velocity of light 

 {Vj^, the velocity of equatorial solar rotation (w^), and Earth's secular eccen- 

 tricity. The reaction of gravitation against photodynamic action, at the 

 centre of any stellar system, requires that 



Modulus of light : Stellar semi- circumference :: «, :v,. 



