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"Tesis ini menguraikan pengembangan dan pengukuran standar frekuensi pada 88 THz yang didasarkan pada garis E dari transisi P(7) CH4. Untuk maksud tersebut kita menggunakan sebuah laser yang frekuensinya digeser menggunakan efek Zeeman untuk mencapai garis E dari CH4.Laser He-Ne yang digunakan dalam eksperimen ini dibangkitkan menggunakan pelepasan (discharge) RF, yang menghasilkan keluaran laser berderau rendah. Kesesuaian impedansi antara penguatan RF dan laser He-Ne dicapai dengan sangat efektif menggunakan sebuah trafo resonansi.Dari tiga komponen efek Zeeman hanya komponen a digunakan sebagai garis penguat laser dan dua komponen lainnya 6+ dan 7C ditapis oleh uap Methylbromide dan candela Brewster, sehingga laser RF He-Ne berosilasi pada frekuensi tunggal yang dapat diatur dan keluaran laser berderau rendah.Untuk meningkatkan rasio SIN dari pendeteksi spektrum garis absorpsi E, telah dikembangkan sistim dispersi tersaturasi menggunakan laser He-Ne bermode ganda. Sistim ini bekerja sebagai pendeteksi heterodyne internal untuk merekam frekuensi denyut (beat). Sistim ini memperbaiki rasio SIN mencapai faktor 4 sampai 5 kali.Dengan menggunakan sistim tersebut telah dilakukan pengamatan ketergantungan frekuensi pusat garis E terhadap parameter kerja seperti: power laser, lebar modulasi laser dan tekanan methane. Pergeseran frekuensi diukur menggunakan sistim Offset lock dengan komponen pusat dari hyperfineyang terurai sebagai referensi yang stabil. Diperoleh untuk perubahan parameter kerja tertentu pergeseran frekuensi pusat garis E dibatasi antara 100 dan 150 Hz. Juga telah diamati pergeseran frekuensi yang terbesar adalah karena tekanan methane.Untuk pengukuran frekuensi absolut dan garis E, laser Zeeman He-Ne distabilkan menggunakan sebuah sistim deteksi ganda yang unik, yang telah dikembangkan dalam percobaan Penentuan frekuensi absolut garis E dilakukan menggunakan rantai pengukuran frekuensi yang ber-phasa koheren, yang dihubungkan dengan jam Cs dari PTB. Sebagai hasil dari pengukuran ini diperoleh frekuensi pusat garis E :vE = 88 373 149 028 553 ± 230 Hz, ini menunjukkan penambahan ketelitian yang cukup berarti terhadap pengukuran sebelumnya.

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This thesis describes the development and measurement of a frequency standard at 88 THz, based on E-line of P(7) transition of CI-4 For this propose we use a He-Ne laser tuned by Zeeman effect to E-line.

The He-Ne laser used in this experiment is excited by RF-discharge, which gives a low noise laser output. The matching condition of the impedance between RF power amplifier and the He-Ne laser is achieved more effectively by using a resonator transformer.

From three components of the Zeeman effect only 6 component is used as the laser gain line in this experiment and the two a+, n components are suppressed by methylbromide vapour and Brewster window respectively, so that the E-line RF He-Ne laser oscillates at a single adjustable frequency with a low noise laser output.

To enhance the SIN ratio of the detection of the E-line absorption spectrum, a saturated dispersion system using a double mode RF He-Ne laser have been studied and developed. This system works as an ideal internal heterodyne detector for recording the beat frequency. As a result the SIN ratio is improved by a factor of 4 to 5 times.

Employing this detection system has been carried out to study the dependency of the E-line center frequency on the operating parameters such as the laser power, the laser modulation width and the methane pressure. The frequency shift was measured by using an offset lock system with respect to the center component of the hyperfine resolved F2 -line as a stable reference. It was found that within the variation range of the operatings parameters the center frequency shift of the E-line, was limited between 100 and 150 Hz. It was also observed that the largest frequency shift was due to methane gas pressure.

For measurement of the absolute frequency of the E-line, the Zeeman tuned He-Ne laser was stabilized using an unique double detection system, which was developed in this work. The determination of the absolute frequency of the E-line was carried out using a phase coherent frequency measurement chain linked to a Cs clock of PTB. As the result of this measurement the E-line center frequency of CH4 was found to be:

vE = 88 373 149 028 553 ± 230 Hz and this result shows a substantial increasing accuracy over the previous measurements."

"[ABSTRAKLatar belakang: Salah satu bagian dalam menentukan diagnosis dan rencana perawatan ortodonti adalah analisis profil jaringan lunak pasien. E-line & Profil wajah merupakan metode yang dapat dipakai dalam menentukan profil jaringan lunak. Pengukuran E-line dan Profil Wajah dinyatakan dapat dilakukan antara Sefalogram dan foto Ekstra Oral. Tujuan: Mengetahui perbedaan posisi Ls, Li dari E-line dan Profil Wajah pada Sefalogram dan foto Ekstra Oral. Metode Penelitian: Didapatkan 55 sampel penelitian berupa Sefalogram lateral dan foto Ekstra Oral lateral. Dilakukan tabulasi data dan diuji komparatif sederhana dengan Chi-square untuk membandingkan posisi Ls, Li dari E-line dan Profil Wajah pada sefalogram dan foto ekstra oral. Hasil: Terdapat perbedaan yang bermakna untuk posisi Ls terhadap garis E-line antara Sefalogram dan foto Ekstra Oral (p< 0,05), terdapat perbedaan yang bermakna untuk posisi Li terhadap garis E-line antara Sefalogram dan foto Ekstra Oral (p<0,05). Terdapat perbedaan yang bermakna untuk Profil Wajah antara Sefalogram dan foto Ekstra Oral (p<0,05). Kesimpulan: Posisi Ls, Li dari E-line dan Profil Wajah pada Sefalogram dan foto Ekstra Oral adalah berbeda.ABSTRACTBackground: Factors in determining the diagnosis and orthodontic treatment plan is the analysis of soft tissue profile of the patient. E-line measurement and profile can be done in the face of otherwise sefalogram and extra-oral photos. Purpose: To determine differences in position Ls, Li from E-line and soft tissue profile on sefalogram and extra-oral photos. Methods: There were 55 samples of research in the form of sefalogram lateral and lateral extra-oral photos. Conducted a comparative tabulation of the data and then tested with Chi-square to compare the position Ls, Li from E-line and soft tissue profile on sefalogram and extra-oral photos. Results: There were significant differences Ls position to the line E-line at sefalogram and extra-oral photograph (p <0.05), there were significant differences Li position to the line E-line at sefalogram and extra-oral photograph (p <0.05 ), there were significant differences in the facial profile and photo sefalogram extra-oral (p <0.05). Conclusion: The position Ls, Li from E-line and soft tissue profile on sefalogram and extra-oral photograph is different.;Background: Factors in determining the diagnosis and orthodontic treatment plan is the analysis of soft tissue profile of the patient. E-line measurement and profile can be done in the face of otherwise sefalogram and extra-oral photos. Purpose: To determine differences in position Ls, Li from E-line and soft tissue profile on sefalogram and extra-oral photos. Methods: There were 55 samples of research in the form of sefalogram lateral and lateral extra-oral photos. Conducted a comparative tabulation of the data and then tested with Chi-square to compare the position Ls, Li from E-line and soft tissue profile on sefalogram and extra-oral photos. Results: There were significant differences Ls position to the line E-line at sefalogram and extra-oral photograph (p <0.05), there were significant differences Li position to the line E-line at sefalogram and extra-oral photograph (p <0.05 ), there were significant differences in the facial profile and photo sefalogram extra-oral (p <0.05). Conclusion: The position Ls, Li from E-line and soft tissue profile on sefalogram and extra-oral photograph is different., Background: Factors in determining the diagnosis and orthodontic treatment plan is the analysis of soft tissue profile of the patient. E-line measurement and profile can be done in the face of otherwise sefalogram and extra-oral photos. Purpose: To determine differences in position Ls, Li from E-line and soft tissue profile on sefalogram and extra-oral photos. Methods: There were 55 samples of research in the form of sefalogram lateral and lateral extra-oral photos. Conducted a comparative tabulation of the data and then tested with Chi-square to compare the position Ls, Li from E-line and soft tissue profile on sefalogram and extra-oral photos. Results: There were significant differences Ls position to the line E-line at sefalogram and extra-oral photograph (p <0.05), there were significant differences Li position to the line E-line at sefalogram and extra-oral photograph (p <0.05 ), there were significant differences in the facial profile and photo sefalogram extra-oral (p <0.05). Conclusion: The position Ls, Li from E-line and soft tissue profile on sefalogram and extra-oral photograph is different.]"

"Latar Belakang: Hal dasar dalam penentuan rencana perawatan ortodonti ialah melihat posisi dan inklinasi dari gigi insisif rahang atas dan rahang bawah, akan tetapi penempatan posisi dan inklinasi gigi insisif yang sesuai dengan kriteria parameter sefalometri normal tidak menjamin bahwa jaringan lunak di atasnya akan menghasilkan tampilan wajah yang harmonis. Hal ini disebabkan karena adanya variasi jaringan lunak antar etnis atau ras.Tujuan: Mengetahui hubungan antara inklinasi gigi insisif dan posisi bibir berdasarkan analisis sefalometri pada pasien ras Deutro-Melayu di klinik ortodonti RSKGM FKG. Metode: Penelitian ini merupakan penelitian kuantitatif dengan menggunakan metode penelitian analitik restropektif cross sectional pada 64 radiograf sefalometri pasien di klinik ortodonti RSKGM FKG UI. Uji korelasi Spearman dilakukan antara nilai parameter inklinasi gigi insisif (UI-Mx, IMPA, Interincisal Angle) dengan nilai parameter posisi bibir berdasarkan E-line. Hasil: Terdapat korelasi signifikan positif yang lemah antara UI-Mx dan posisi biibr bawah (r=0,294*). Terdapat korelasi signifikan negatif yang lemah antara Interincisal Angle dan posisi bibir bawah (r=-0,323*). Namun tidak terdapat korelasi antara UI-Mx, IMPA dan Interincisal Angle dengan bibir atas, serta IMPA dengan bibir bawah. Kesimpulan: Tidak terdapat hubungan antara inklinasi gigi insisif (UI-Mx, IMPA, Interincisal Angle) dan posisi bibir berdasarkan E-line.

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Background: The basic thing in an orthodontic treatment plan is to look at the position and inclination of the maxillary and mandibular incisors, but the placement and inclination of the incisors according to the criteria for normal cephalometric parameters does not guarantee that the overlying soft tissues will produce a harmonious facial appearance. This is due to soft tissue variations between ethnicities.

Objective: To determine the relationship between incisor teeth and lip position based on cephalometric analysis in Deutro-Malay patients at the orthodontic clinic of RSKGM FKG.

Method: This study is a quantitative study using a cross-sectional retrospective analytic research method on 64 patients with cephalometric radiographs at the orthodontic clinic of RSKGM FKG UI. Spearman correlation test was performed between the incisor inclination parameter values ​​(UI-Mx, IMPA, Interincisal Angle) and the lip position parameter values ​​based on the E-line.

Results: The correlation test showed that there was weak positive significant between UI-Mx and lower lip position (r=0.294*). There was a weak negative significant correlation between Interincisal Angle and lower lip position (r=-0.323*). However, there was no correlation between UI-Mx, IMPA and Interincisal Angle with the upper lip, and IMPA with the lower lip.

Conclusion: There is no relationship between incisor inclination (UI-Mx, IMPA, Interincisal Angle) and lip position based on E-line.

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