\font\twelverm=cmr12 \font\twelvebf=cmbx12 \font\twelveit=cmti12 \font\ninerm=cmr9 \font\nineit=cmti9 \font\ninesy=cmsy9 \font\ninemi=cmmi9 \font\sevenrm=cmr7 \font\sevenit=cmti7 \font\sevensy=cmsy7 \font\sevenmi=cmmi7 \font\twelvesy=cmsy10 scaled \magstep1 \font\twelvemi=cmmi10 scaled \magstep1 \def\bigtype{\let\rm=\twelverm \let\bf=\twelvebf \let\it=\twelveit \textfont2=\twelvesy \textfont0=\twelverm \textfont1=\twelvemi \scriptfont0=\ninerm \scriptfont1=\ninemi \scriptfont2=\ninesy \scriptscriptfont2=\sevensy \scriptscriptfont0=\sevenrm \scriptscriptfont1=\sevenmi \baselineskip=16pt \rm} \bigtype \parindent 0.5 in \parskip 5 pt \hsize 7.0 in \vsize 9.5 in \hoffset -0.3 in \voffset -0.2 in \centerline{\bf Notes to Table 1 (Hartkopf et al., 1993, AJ, 106, 352} \vskip 0.3 in \parindent 0.0 in \def\bpar{\hangafter=1\hangindent=1.0 in} \bpar {\bf 00283$-$2020 = B 1909:} This has long been a difficult visual system, with the two components remaining within 0$''$\llap.2 of each other throughout the orbit. With this observation we have completed a full revolution using speckle data alone, and have derived new orbital elements which will be published shortly. \bpar {\bf 00479$-$2921 = I 261:} Having had only one other measure in the last 35 years, this pair needs further observation, especially since we appear to be near periastron at this epoch. \bpar {\bf 01243$-$0655 = Bu 1163:} A new interferometric orbit of this very eccentric (e = 0.94) system is in preparation. \bpar {\bf 02396$-$1153 = Fin 312:} Residuals from the orbit of Hartkopf et al. (1989, AJ, 98, 1014) are (0$^{\circ}$\llap.2, -0$''$\llap.003). \bpar {\bf 02398$+$0009 = A 1928:} Periastron passage for this very close visual pair has thus far been well covered by speckle. \bpar {\bf 02518$-$2117 = See 21:} This very close visual system was discovered at a separation of 0$''$\llap.36 and has closed steadily for over 90 years. It is unknown at this point whether the system is still approaching periastron or has begun to widen. \bpar {\bf 03544$-$4021 = Fin 344 AB:} This is the first observation of this system since those of Finsen in the 1960's, and is considerably closer than any of his results. It is known that in some instances Finsen's $\rho$ values appeared systematically larger than those of speckle; further observations of this system will determine whether such is again the case. \bpar {\bf 04037$-$1545 = A 2913:} This system closed steadily from its discovery at 0$''$\llap.45 in 1915 to 0$''$\llap.22 in 1959; this is the first observation in 30 years so it is unknown whether the pair has passed through periastron. \bpar {\bf 04256$+$1557 = Fin 342 Aa:} Residuals from the orbit of McAlister et al. (1988, AJ, 96, 1431) are (-2$^{\circ}$\llap.3, 0$''$\llap.008). \bpar {\bf 05248$-$5219 = I 345 AB:} This system has also decreased in separation steadily since the 1920's, and was last resolved visually in 1983. \bpar {\bf 05565$-$2631 = B 94:} This system was last resolved visually in 1978, and appears to be continuing to approach periastron. \bpar {\bf 07003$-$2207 = Fin 334 Aa:} The system has opened slightly since the last speckle observation in 1989.3; unfortunately it was last observed in 1966 so it may be difficult to pin down the time of periastron passage. \bpar {\bf 08125$-$4616 = CHARA 143 Aa:} These measurements confirm the discovery observation of this close companion to See 96, made in the spring of 1989. \bpar {\bf 08285$-$0230 = A 551 AB:} Speckle observations are in poor agreement with the orbit of van den Bos (1953, Union Obs. Circ., 6, 211). A new orbit is in preparation. \bpar {\bf 09123$+$1459 = Fin 347 Aa:} Residuals from the orbit of Hartkopf et al. (1989, AJ, 98, 1014) are (-0$^{\circ}$\llap.3, -0$''$\llap.003) and (-3$^{\circ}$\llap.2, 0$''$\llap.003). \bpar {\bf 10120$-$2836 = B 194:} Periastron passage apparently occurred about the time of or shortly before our first speckle observation in 1989.3. \bpar {\bf 12597$-$0348 = CHARA 39 Aa:} This interferometric system has now completed nearly 180$^{\circ}$\thinspace of revolution since its discovery in 1984. A preliminary determination of orbital elements yields a low--eccentricity orbit with a period of 15.7 years. Absolute quadrant determinations based on reanalysis of earlier speckle data have ruled out a possible short--period high--eccentricity orbit. A more complete orbital analysis is in progress. \bpar {\bf 14373$+$0217 = CHARA 42 Aa:} This system apparently is continuing to close toward periastron. \bpar {\bf 16057$-$0617 = Fin 384 Aa:} Residuals from the orbit of Baize (1992, A\&AS, 92, 31) are (-4$^{\circ}$\llap.5, 0$''$\llap.003). \bpar {\bf 16245$-$3734 = B 868:} This system may have made a very close periastron passage between the times of our 1989.3 observation ($\rho$ = 0$''$\llap.039) and this one, although unfortunately the system was not observed in 1990. \bpar {\bf 16391$-$3713 = Fin 340 AB:} From its discovery in 1954 through the mid-1960's, this system closed from 0$''$\llap.14 to 0$''$\llap.10 and increased in $\theta$ from 147$^{\circ}$\thinspace to 172$^{\circ}$\llap.~ It is impossible to determine from this single speckle measure whether the pair has gone through periastron and flipped quadrant, but this should become obvious within the next couple of observations. \bpar {\bf 16438$-$5330 = Fin 251 AB:} The close third component CHARA 147 Aa discovered in 1989.3 was unfortunately not confirmed in these observations. \bpar {\bf 17207$-$5625 = Fin 255 AB:} This observation finally confirms the discovery of this system by Finsen, made in 1931! \bpar {\bf 19253$-$2431 = Fin 327:} With 15 years of speckle data on this system we are finally able to attempt to improve upon Finsen's (1965, Republic Obc. Circ., 7, 85) orbital elements. We apparently view the pair at a nearly 90$^{\circ}$\thinspace inclination and since the $\Delta$m for the components is near zero there is considerable ambiguity between a high--eccentricity short--period orbit and a low--eccentricity long-period one. A new orbital analysis is now in preparation, including reanalysis of earlier speckle data in order to derive absolute quadrants and possibly resolve this ambiguity. \vfill\eject\end