Ουλούγ Μπεκ: ο Αστρονόμος Σουλτάνος του Τουρκεστάν, ο πιο Πολυμαθής Αυτοκράτορας των Τελευταίων 2500 Ετών, Εγγονός του Ταμερλάνου

Ουλούγ Μπεκ: ο
Αστρονόμος Σουλτάνος
του Τουρκεστάν, ο πιο
Πολυμαθής
Αυτοκράτορας των
Τελευταίων 2500
Ετών, Εγγονός
του Ταμερλάνου
https://greeksoftheorient.wordpress.com/2019/08/05/ο
υλούγ-μπεκ-ο-αστρονόμος-σουλτάνος-το/
===============
Οι Ρωμιοί της Ανατολής –
Greeks of the Orient

Ρωμιοσύνη, Ρωμανία, Ανατολική Ρωμαϊκή
Αυτοκρατορία
Ουλούγ Μπεκ: ο
Αστρονόμος Σουλτάνος
του Τουρκεστάν, ο πιο
Πολυμαθής
Αυτοκράτορας των
Τελευταίων 2500
Ετών, Εγγονός
του Ταμερλάνου
Τα αστρονομικά συγγράμματά του
μεταφράζονταν στα λατινικά από τους

Ευρωπαίους ακόμη αιώνες αργότερα. Ο ίδιος
βασίλευσε ήδη πριν πέσει η
Κωνσταντινούπολη στους Οθωμανούς.
Ρωμιοί μαθηματικοί εργάζονταν στα
ερευνητικά κέντρα, το πανεπιστήμιο και
τις βιβλιοθήκες του. Το αστεροσκοπείο του
ήταν το σημαντικώτερο στον κόσμο ως
βελτίωση εκείνου της Μαραγέ (σήμερα στο
Ιράν), όπου εκείνος είχε σπουδάσει. Η
πρόοδος των επιστημών στα χρόνια του
ήταν εντυπωσιακή και οι μελέτες και τα
συμπεράσματά του διαδόθηκαν από την μια
άκρη του κόσμου στην άλλη. Οι αστρικοί
κατάλογοί του ήταν οι ακριβέστεροι, κι ο
ίδιος έκανε με το μυαλό του αδιανόητους
υπολογισμούς – ακόμη κι όταν ήταν
έφιππος σε εκστρατεία – που απόλυτα
επιβεβαιώνονταν υστερογενώς πάνω στο
χαρτί.

Απήγγειλε από στήθους το Κοράνι (που έχει
περίπου τόση έκταση όση κι η Καινή
Διαθήκη) αλλά ήταν ένας εξαιρετικός

επιστήμονας και θαυμάσιος δάσκαλος που
έντονα επιζητούσε την αμφισβήτηση για να
υπάρχει αντίλογος και στην συνέχεια
επαλήθευση των συμπερασμάτων. Ο ίδιος
αποτελούσε την ζωντανή παρακαταθήκη
των ισλαμικών επιστημών και των
επιστημών όλων των προϊσλαμικών
πολιτισμών που είχαν μελετηθεί από
μουσουλμάνους επιστήμονες και σοφούς στο
Μπέιτ αλ Χέκμα της Βαγδάτης, 700 χρόνια
νωρίτερα. Και το μνημειώδες αστεροσκοπείο
του (σε εποχή που δεν υπήρχαν ακόμη τα
μικροσκόπια) δεν είχε τίποτα να ζηλέψει
από κείνα που αναγέρθηκαν 150 χρόνια
αργότερα από τον Τύχο Μπράχε στην Δανία
και από τον Τακιεντίν Εφέντη στην
Σταμπούλ. Στα μέσα του 15ου αιώνα, όλοι
οι δρόμοι οδηγούσαν στην Σαμαρκάνδη του
Ουλούγ Μπεκ!

Εγγονός του Ταμερλάνου και γιος του
Σαχρούχ, ο Ουλούγ Μπεκ ήταν η ζωντανή
επιβεβαίωση του γεγονότος ότι δεν υπάρχει
ουσιαστικά καμμιά διαφορά ανάμεσα σε Ιράν
και Τουράν και ότι οι νεώτεροι δυτικοί
οριενταλιστές έχουν παραχαράξει ολότελα
την Ιστορία της Ασίας για να δημιουργήσουν
ψευδείς εντυπώσεις και γενικευμένη
σύγχυση.

Προσέξτε: ο Τουρανός πατέρας του Ουλούγ
Μπεκ βασίλευσε στην Σαμαρκάνδη, η
μητέρα του Ουλούγ Μπεκ, Γκοχαρσάντ,
συνεισέφερε στην ανέγερση ενός από τα πιο
σημαντικά ‘ιρανικά’ τζαμιά στο σύμπλεγμα
ιερών της Μασάντ, στο σημερινό ΒΑ Ιράν
(όπου βρίσκονται ενταφιασμένοι ο Αβασίδης
χαλίφης Χαρούν αλ Ρασίντ κι ο πέμπτος
ιμάμης του Ισλάμ, Ρεζά), ενώ ο ίδιος ο
αστρονόμος σουλτάνος βασίλευσε επίσης στη
Σαμαρκάνδη (Αφρασιάμπ) στο σημερινό
Ουζμπεκιστάν.
Με τα δεδομένα των δυτικών
οριενταλιστών, η μητέρα του Ουλούγ Μπεκ
αποτελεί θέμα ιρανολογίας αλλά ο ίδιος ο
Ουλούγ Μπεκ τμήμα τουρκολογίας! Αστείο!

Πρέπει να ομολογήσω ότι για δεκαετίες δεν
είχα ιδιαίτερα προσέξει τον Ουλούγ Μπεκ,
αν και βέβαια είχα ταξιδέψει στο
Ουζμπεκιστάν και επισκεφθεί την
Σαμαρκάνδη ήδη στα χρόνια της ΕΣΣΔ
(στην δεκαετία του 1980). Το όνομα μου
ήταν γνωστό αλλά αυτό ήταν όλο! Βεβαίως
είχα δει από κοντά το εντυπωσιακό και
τεράστιο πανεπιστήμιο (μεντρεσά) του
Ουλούγ Μπεκ στην περιοχή Ρετζιστάν της
Σαμαρκάνδης – ένα τόπο όπου, αν
περπατήσεις, νομίζεις ότι ονειρεύεσαι. Αλλά
δεν ήξερα τίποτα περισσότερο και οι
οργανωμένες εκδρομές στην ΕΣΣΔ (όπως
και όλες οι οργανωμένες εκδρομές εν παντί
τόπω και καιρώ) ήταν μια αθλιότητα που
δεν σου επέτρεπε να αφιερώσεις όσο χρόνο
θέλεις σε ένα ξεχωριστό μνημείο που
ερεθίζει την περιέργειά σου.

Αλλά πριν από μερικά χρόνια, η γνωριμία
μου με τον Έλληνα ανατολιστή ιστορικό και
πολιτικό επιστήμονα, καθ. Μουχάμαντ
Σαμσαντίν Μεγαλομμάτη, και οι συζητήσεις
μου μαζί του αποτέλεσαν την ευκαιρία να
κατανοήσω κάτι το πολύ καθοριστικό που
λίγοι δυστυχώς αντιλαμβάνονται: δεν έχει
σημασία να πας κάπου και να δεις το
ό,τιδήποτε. Σημασία έχει να αντιλαμβάνεσαι
το που βρίσκεσαι, το τι βλέπεις, και το τι
κρύβεται πίσω από αυτά.

Έτσι, χάρη σε μερικές καθοριστικές
αναφορές του κ. Μεγαλομμάτη στους Ζιτζ-ε
Σολτάνι (Αστρικοί Κατάλογοι ή Πίνακες του
Σουλτάνου), ένα μνημειώδες αστρονομικό
έργο του Ουλούγ Μπεκ, το οποίο
διασώζεται μέχρι σήμερα, και στο πως και
μετά από πόση και ποια έρευνα γράφονταν
τα στοιχεία που αναφέρονται στο έργο αυτό,
κατάλαβα ότι έπρεπε να … ‘ξανα-
επισκεφτώ’ τον εγγονό του Ταμερλάνου –
έστω μέσω του Ιντερνέτ και αρκετών
αναγνωσμάτων.
Βασιλεία, Σοφία και Επιστήμη

Αναμφίβολα υπήρξαν αρκετοί αυτοκράτορες
στην Ιστορία που επέδειξαν ιδιαίτερο ή και
σπάνιο ζήλο για την θεουργία, την ενόραση,
την σοφία, την γνώση, την επιστήμη, τα
γράμματα, και τις τέχνες. Ένας από αυτούς
ήταν ο Ασσουρμπανιπάλ (669-625),
αυτοκράτορας της Ασσυρίας, ο οποίος ως
μέγας αρχιερέας ήταν γνώστης των
σφηνοειδών ασσυροβαβυλωνιακών, των
ασσυριακών επιστημών, κοσμογονιών και
θεουργιών. Ο ίδιος ήταν και ο πρώτος
επώνυμος στην Παγκόσμια Ιστορία που είχε
μάθει μια ήδη στα χρόνια του νεκρή
γλώσσα: τα σουμεριακά, τα οποία ήταν τότε
ό,τι τα λατινικά για τους Ευρωπαίους
επιστήμονες των τελευταίων αιώνων. Στα
χρόνια του αυτοκράτορα της Νινευή, τα
σουμεριακά ήταν ήδη νεκρή γλώσσα για
1300 χρόνια! Μοναδικός ηγεμόνας και
στρατηλάτης τον οποίο ζήλεψε ακόμη και ο
Μέγας Αλέξανδρος, επειδή ο Ασσύριος
αυτοκράτορας είχε καταλάβει την Τύρο μετά
από ιδιαίτερα σύντομο χρονικό διάστημα
πολιορκίας!

Και σε πολλούς μονάρχες αποδίδονται
ξεχωριστά έργα και κείμενα που αποτελούν
ορόσημα της Παγκόσμιας Ιστορίας. Αλλά
αυτά τα έργα δεν είναι πάντοτε ακριβώς
‘δικά’ τους. Θα αναφέρω μερικά
παραδείγματα:
Στον Πτολεμαίο Β’ αποδίδονται πολλά και
ανάμεσά τους η μετάφραση της Παλαιάς
Διαθήκης των αρχαίων Εβραίων στα
ελληνικά (η μετάφραση των Ο’). Αλλά δεν
μετέφρασε ο ίδιος ο Πτολεμαίος Β’ την
εβραϊκή Βίβλο. Προσκάλεσε 70 ραβίνους
που έκαναν την δουλειά εργαζόμενοι σε ένα
κτήριο στο νησί του Φάρου στην
Αλεξάνδρεια.
Η Κλεοπάτρα ήταν γνωστό ότι μιλούσε
άπταιστα επτά γλώσσες. Αλλά δεν
συνέγραψε τίποτα.
Στον Καίσαρα αποδίδεται το περίφημο
Ιουλιανό ημερολόγιο που ακόμη τηρούν οι
κακώς λεγόμενοι ‘παλιοημερολογίτες’. Αλλά
αυτό δεν ήταν έργο του ίδιου του Καίσαρα
αλλά του αστρονόμου Σωσιγένη τον οποίο ο

Καίσαρας γνώρισε στην αυλή της
Κλεοπάτρας και από τον οποίο ζήτησε ο
Ρωμαίος στρατηλάτης ένα νέο ημερολόγιο.
Στον κορυφαίο αυτοκράτορα Ιουστινιανό
αποδίδεται η σημαντικώτερη χριστιανική
νομοθεσία, η οποία αποτελούσε συγκερασμό
της χριστιανικής πίστης και ηθικής, των
χριστιανικών αξιών, και του παλαιότερου,
προ-χριστιανικού ρωμαϊκού Δικαίου: αλλά
δεν συνέγραψε ο ίδιος ο Ιουστινιανός τις
Νεαρές και τα άλλα τμήματα του Corpus
Δικαίου το οποίο εισήγαγε. Αυτό ήταν το
έργο του Τριβωνιανού.
Για να έλθουμε πιο κοντά στα χρόνια του
Ουλούγ Μπεκ, θα αναφερθώ στον
Κωνσταντίνο Ζ’ Πορφυρογέννητο που γύρω
στα μισά του 10ου αιώνα έγραψε ανάμεσα
σε άλλα έργα το Περί βασιλείου τάξεως, το
Προς τον ίδιον υιόν Ρωμανόν, και το Περί
θεμάτων. Πολύ αξιόλογα έργα, αναμφίβολα.
Λόγιος ο αυτοκράτορας της Ρωμανίας,
σίγουρα. Αλλά το περιεχόμενο αυτών των
έργων είναι η περιγραφή της διοικητικής

μηχανής και του αυλικού εθιμοτυπικού της
Ρωμανίας – όχι επιστημονική παρατήρηση
και καταγραφή.
Εξίσου λόγιος ήταν και ο πατέρας του
Πορφυρογέννητου Λέων ΣΤ’ Σοφός.
Συγγραφέας, ρήτορας και ποιητής. Αλλά όχι
επιστήμονας, μαθηματικός κι αστρονόμος.
Σύγχρονος του Ουλούγ Μπεκ ήταν ο
Μανουήλ Β’ Παλαιολόγος (1350-1425).
Εδώ ερχόμαστε πολύ κοντά όταν κάνουμε
συγκρίσεις. Ο προ-προτελευταίος βασιλεύς
της Ρωμανίας ήταν ένας ευρυμαθής
ηγεμόνας και λόγιος, θεολόγος και
συγγραφέας: είχε συγγράψει μια τεράστια
πραγματεία για την Λιτανεία του Αγίου
Πνεύματος. Είχε συνδιαλεχθεί με Ιρανούς
(Πέρσες) θεολόγους και σοφούς,
εκτεινόμενος σε θέματα θεολογικά και
ιστορικοθησκευτικά και συνδιαλεγόμενος
σχετικά με συγκρίσεις της Χριστιανωσύνης
και του Ισλάμ.
Αυτοί οι διάλογοι που έγιναν στην Άγκυρα
το 1391 έγιναν αντικείμενο αναφοράς από

τον Πάπα Βενέδικτο ΙΣΤ’ το 2006, όταν
ξέσπασε – πολύ κακώς – σχετικός σάλος.
Ο Μανουήλ Β’ Παλαιολόγος, ο οποίος ήταν
44 χρόνια μεγαλύτερος του Ουλούγ Μπεκ
και πέθανε 24 χρόνια πριν δολοφονηθεί ο
σουλτάνος του Τουρκεστάν, δεν ήταν
μαθηματικός κι αστρονόμος.
Ουλούγ Μπεκ (1394-1449)
Το πραγματικό όνομα του Ουλούγ Μπεκ
ήταν Μιρζά Μουχάμαντ Ταραγάυ μπιν
Σαχρούχ (λατ. Mīrza Muhammad
Taraghay bin Shahrukh, τσαγατάυ: ‫میرزا‬
‫رخ‬ ‫شاہ‬ ‫بن‬ ‫طارق‬ ‫محمد‬, φαρσί: ‫رخ‬ ‫شاہ‬ ‫بن‬ ‫تراغای‬ ‫محمد‬ ‫میرزا‬).
Η πατρική του γλώσσα ήταν τα τσαγατάυ,
μια τουρκική (Turkic) γλώσσα που σήμερα
πλέον δεν ομιλείται, μείγμα μογγολικών
και ανατολικών τουρκικών. Έμεινε
περισσότερο γνωστός ως Ουλούγ Μπεκ,

δηλαδή ‘Μέγας Ηγεμόνας’ (λατ. Ulugh Beg,
φαρσί: ‫بیگ‬ ‫الغ‬). Στα σύγχρονα τουρκικά οι δυο
λέξεις είναι ulu bey, αλλά στα οθωμανικά
χρόνια η λέξη bey (μπέης) έχασε την αρχικά
μεγάλη σημασία της, λόγω της ανόδου της
σημασίας άλλων όρων (σουλτάν, παδισάχ).
Ως όρος, το ‘Ουλούγ Μπεκ’ είναι το
τουρκικό (Turkic) αντίστοιχο του περσο-
αραβικού Αμίρ-ε Καμπίρ.
Ο ίδιος ο Ουλούγ Μπεκ μιλούσε άπταιστα
αραβικά, περσικά, τουρκικές και μογγολικές
γλώσσες, και επίσης κινεζικά. Γεννήθηκε σε
μια κοσμοπολίτικη πρωτεύουσα κτισμένη
200 χρόνια νωρίτερα όπου συνέρρεαν
επιστήμονες και σοφοί, θεολόγοι και
ιστορικοί από όλη την Ασία: την
Σουλτανίγιε (Σουλτανική), όταν ο νεαρός
πατέρας του δεν είχε ακόμη ανακηρυχθεί
σάχης και σουλτάνος στην Σαμαρκάνδη. Ο
Ουλούγ Μπεκ σπούδασε τριγωνομετρία,
σφαιρική γεωμετρία και αστρονομία στην
Μαραγέ, όπου βρισκόταν το πιο σημαντικό
αστεροσκοπείο του τότε κόσμου, στο οποίο

200 χρόνια πιο πριν εργαζόταν, ερευνούσε
κι έγραφε ο Νασρεντίν αλ Τούσι, ένας από
τους μεγαλύτερους σοφούς όλων των
εποχών.
Υπάρχει μια ανθρώπινη πλευρά που φέρνει
τον Ουλούγ Μπεκ σε παράλληλη τροχιά με
τον σημερινό πρίγκιπα Κάρολο της Αγγλίας!
Ο Σαχρούχ (1377-1447) γέννησε τον
Ουλούγ Μπεκ (1394-1449) σε πολύ νεαρή
ηλικία (όταν ήταν 17 ετών) και πριν
ανεβεί στον θρόνο, όπως και η βασίλισσα
Ελισάβετ Β’ τον Κάρολο (και πριν εκείνη
γίνει βασίλισσα).
Στην συνέχεια, ο Σαχρούχ ανακηρύχθηκε
σάχης και σουλτάνος στα 28 του και

βασίλευσε για πολλά (42) χρόνια (1405–
1447), όπως κι η Ελισάβετ Β’ μέχρι
σήμερα. Ο Ουλούγ Μπεκ ήταν 11 ετών,
όταν πέθανε ο παπούς του, ο Ταμερλάνος,
κι ο πατέρας του ανακηρύχθηκε βασιλιάς.
Κι έτσι παρέμεινε διάδοχος του θρόνου
(όπως κι ο Κάρολος ακόμη) για μια πολύ
μεγάλη χρονική περίοδο, μέχρις ότου
ανακηρυχθεί ο ίδιος βασιλιάς σε σχετικά
μεγάλη ηλικία, στα 53 του (στην
περίπτωση του Καρόλου της Αγγλίας η
κατάσταση έχει βέβαια φτάσει σε ακόμη πιο
ακραία σημεία!).

Συνέπεια αυτής της κατάστασης ήταν η
απρόσκοπτη στροφή κι αφοσίωση του
διαδόχου του θρόνου στις επιστήμες και
στην έρευνα. Ανέγειρε το πανεπιστήμιο
(μεντρεσά) το 1417-1420, όταν ο ίδιος
ήταν 23-26 ετών, και στην συνέχεια,
αστεροσκοπείο της Σαμαρκάνδης στην
περίοδο 1424-1429, όταν ο ίδιος ήταν 30-
35 ετών.
Το αστεροσκοπείο ήταν ένα από τα
μεγαλύτερα κτίσματα εκείνων των χρόνων
και ο φαχρί εξάντας του είχε ακτίνα 40.4
μέτρα! Σπουδαίοι ερευνητές, επιστήμονες
και μαθηματικοί προσέτρεξαν να εργαστούν
εκεί, όπως ο Πέρσης Τζαμσίντ αλ Κασί και
ο Ρωμιός Καντί Ζαντέ ερ-Ρουμί (1364-
1436). Επειδή αυτός γεννήθηκε στην
Προύσα λίγες δεκαετίες μόνον μετά την
οθωμανική κατάκτηση της πόλης είναι
πιθανώτατο ότι είτε ο ίδιος είτε ο πατέρας
του είχε γεννηθεί Χριστιανός Ορθόδοξος και
στην συνέχεια αλλαξοπίστησε. Το γεγονός
ότι επονομαζόταν Ρωμιός σε συνδυασμό με

το δεδομένο ότι προτίμησε την τιμουριδική
επικράτεια αντί της οθωμανικής, όπου
ανήκε, δείχνει καθαρά ότι δεν ήταν
Οθωμανός.
Το έργο του Ουλούγ Μπεκ Ζιτζ-ε Σουλτάνι
είναι ο μεγαλύτερος αστρικός πίνακας από
την εποχή του Πτολεμαίου μέχρι τα χρόνια
του Τύχο Μπράχε. Μεταφραζόταν
ακατάπαυστα από Ευρωπαίους σε λατινικά
για πολλούς αιώνες αργότερα.

Zij 1437
Ο Ουλούγ Μπεκ βασίλευσε μόνο για δύο
χρόνια (1447-1449). Αν και επιστήμονας
ήταν ένας καλός στρατιωτικός και
πολεμιστής. Είχε όμως την τραγική ατυχία
να έχει ένα ανάξιο γιο, ο οποίος από τρομερό
φθόνο οργάνωσε και διεκπεραίωσε ύπουλα
την δολοφονία του τόσο λαμπρού πατέρα
του. Όταν πήγαινε ο Ουλούγ Μπεκ για
προσκύνημα (χατζ) στην Μέκκα, πράκτορες
τον δολοφόνησαν μαζί με τον αδελφό του, ο
οποίος τον ακολουθούσε.
Ο πατροκτόνος Αμπντελατίφ δεν στάθηκε
άξιος ούτε ένα χρόνο να συμπληρώσει στον

άνομο θρόνο του κι έτσι το 1450 ο
‘πανταρκούς’ (στα φαρσί ‘πατροκτόνος’: ‫پدر‬
‫کش‬) δολοφονήθηκε όπως του άξιζε. Ο
ανηψιός του Ουλούγ Μπεκ Αμπντουλάχ
Μιρζά απεκατέστησε την τάξη, διαδεχόμενος
τον ανάξιο γιο του μεγάλου πατέρα, και
μετέφερε την σορό του Ουλούγ Μπεκ στο
ταφικό μνημείο του Ταμερλάνου.
Sic transit gloria mundi ….
Στην συνέχεια θα βρείτε πολλούς
συνδέσμους κι επιλεγμένα αναγνώσματα.
Στοιχειώδη:
Επιστημονική συζήτηση για τον Ουλούγ
Μπεκ στα ρωσσικά:

https://echo.msk.ru/programs/vsetak/513
34/
Σχετικά με τους τόπους όπου γεννήθηκε
και σπούδασε ο Ουλούγ Μπεκ:
https://en.wikipedia.org/wiki/Dome_of_So
ltaniyeh
https://en.wikipedia.org/wiki/Soltaniyeh
https://en.wikipedia.org/wiki/Ilkhanate
https://en.wikipedia.org/wiki/Maragheh_
observatory
Σχετικά με το πανεπιστήμιο και το
αστεροσκοπείο του Ουλούγ Μπεκ στη
Σαμαρκάνδη:
https://en.wikipedia.org/wiki/Ulugh_Beg_
Madrasa,_Samarkand
https://en.wikipedia.org/wiki/Ulugh_Beg_
Observatory
https://web.archive.org/web/2016030411
4956/http://vivovoco.astronet.ru/VV/JOU
RNAL/NATURE/02_02/ULUGBEK.HTM

http://e-
samarkand.narod.ru/Mojeyko_Ulugbek.ht
m
Σχετικά με το έργο του Ουλούγ Μπεκ Ζιτζ-
ε Σουλτάνι:
https://en.wikipedia.org/wiki/Zij-
i_Sultani
http://www.astromyth.ru/Catalogs/Ulughb
eg/
https://en.wikipedia.org/wiki/Sextant_(ast
ronomical)
Σχετικά με τους κυριώτερους
επιστημονικούς συνεργάτες του Ουλούγ
Μπεκ:
https://en.wikipedia.org/wiki/Jamsh%C4
%ABd_al-K%C4%81sh%C4%AB
https://en.wikipedia.org/wiki/Q%C4%81%
E1%B8%8D%C4%AB_Z%C4%81da_al-
R%C5%ABm%C4%AB
Σχετικά με τους συγγενείς του Ουλούγ
Μπεκ (πατέρα, μητέρα, γιο και ανηψιό):

https://en.wikipedia.org/wiki/Shah_Ruk
h
https://en.wikipedia.org/wiki/Goharshad_
Begum
http://www.iranicaonline.org/articles/ab
d-al-latif-mirza-sultan-timurid-ruler-
in-samarqand-1449-50
https://en.wikipedia.org/wiki/Abdal-
Latif_Mirza
https://en.wikipedia.org/wiki/Abdullah_
Mirza
Σχετικά με τον ίδιο τον Ουλούγ Μπεκ:
https://islamsci.mcgill.ca/RASI/BEA/Ulug
h_Beg_BEA.htm
https://en.wikipedia.org/wiki/Ulugh_Beg
http://www.ahmerov.com/book_446_chapt
er_2_1.html
В 1964 году рядом с местом, где
находилась обсерватория, был открыт

мемориальный музей Улугбека. Здесь
выставлены отрывки из знаменитых
таблиц со сведениями о звёздах,
вычисленных Улугбеком и его
соратниками, фотографии раскопок,
коллекция древних астрономических
инструментов, фрески, изображающие
эпизоды жизни астронома
http://www.vokrugsveta.ru/telegraph/hist
ory/350/

Περισσότερα Αναγνώσματα:
Al-Kashi’s letter
A letter from Jamshid al-Kashi to his
father has survived and gives us a rare
glimpse into details of the intellectual life
at UIugh Beg’s court. In this letter
(translated in the book by David A King
and Mary Helen Kennedy (eds.), Studies
in the Islamic exact sciences. Reprints of
papers by E S Kennedy, colleagues and
former students (American University of
Beirut, 1983), p. 724]) al-Kashi describes

at length the accomplishments of UIugh
Beg who, he says:-
… has by heart most of the glorious Quran
… and every day he recites two chapters
in the presence of (Quran) memorizers
and no mistake is made. He knows
(Arabic) grammar well and he writes
Arabic composition extremely well, and
like-wise he is well posted in canon law;
he has knowledge of logic, rhetoric, and
elocution, and likewise of the Elements,
and he himself cultivates the branches of
mathematics, and this has reached the
extent that one day while riding he
wanted to determine the date, which was
a Monday of [the month of] Rajab,
between the fifth and the tenth in the
year eight hundred and eighteen (A. H.),
as to what day it was of the
(astronomical) season of the year. From
these very given data, by mental
computation, and from horseback, he
determined the true longitude of the sun

(correct) to degrees and minutes. When he
came back he asked this humble servant
about it. Truly, since in mental
computation the quantities must be
retained by memory and others
determined, and there is a limit to one’s
strength of retention, he (i.e. I) was not
able to extract it to degrees and minutes,
but contented myself with degrees.
http://www-history.mcs.st-
and.ac.uk/Extras/Al-Kashi_letter.html
====================================
==
Улугбек

Единственный прижизненный портрет
Улугбека. Он значительно отличается
от поздних выдуманных и
идеализированных изображений. Это
групповой портрет, на котором
вполне достоверно изображены сыновья
Улугбека Абд ал-Латиф (старший) и
Абд ал-Азиз (младший) — стоят в
нижнем правом углу; в монгольского
фасона головных уборах сидят на
коврах его жёны, самые ближние: Ак-
Султан Ханике и Хуси-Нигар Ханике;
рядом с Улугбеком стоят трое его
генералов (эмиров) с саблями, слуги, и
в верхнем углу справа — сокольничие.
Рядом с ними можно видеть лук и
колчан полный стрел, то есть Улугбек,
который был страстным охотником,
приготовился к охоте. На крыше
павильона, в котором сидит Улугбек,
надпись гласит: «Султан
величайший, Улугбек Гурган,
благословение царству его». Вероятно,
это правая часть диптиха, поскольку

взоры всех присутствующих
направлены на левую часть, где были
изображены какие-то любопытные
события. Миниатюра создана
неизвестным придворным художником
в 1425—1450 гг. Художественная
галерея Фрира, Вашингтон.
https://ru.wikipedia.org/wiki/Улугбек
================================
The Legacy of Ulugh Beg
By Kevin Krisciunas 1

Muhammed Taragai Ulugh Beg (1394-
1449) was a Turk who ruled the province
of Transoxiana (Maverannahr), a region
situated between the River Oxus (Amu
Darya) and the River Jaxartes (Syr
Darya), the principal city of which was
Samarkand. Ulugh Beg’s grandfather was
the famous conqueror Timur (1336-
1405). Ulugh Beg became the ruler of
Transoxiana in 1447 upon the death of
his father. But his rule was of short
duration. Two years later he was killed
by an assassin hired by his son ‘Abd al
Latif.
Were it only for his role as prince,
viceroy, and martyr, few scholars would
know of Ulugh Beg. But his memory lives
on because he was an observatory builder,
patron of astronomy, and astronomer in
his own right. He was certainly the most
important observational astronomer of the
15th century. He was one of the first to
advocate and build permanently mounted

astronomical instruments. His catalogue of
1018 stars (some sources count 1022) was
the only such undertaking carried out
between the times of Claudius Ptolemy
(ca. 170 A.D.) and Tycho Brahe (ca.
1600). And, as we shall briefly discuss
here, his attitude towards scientific
endeavors was surprisingly modern.
The administration of Transoxiana was
the responsibility of Ulugh Beg’s father for
most of Ulugh Beg’s life. The prince had
the opportunity (and the inclination) to
pursue scholarly matters. His interest in
astronomy dates from an early age, when
he visited the remains of the Maragha
Observatory, made famous by the
astronomer Nasir al-Din al-Tusi (1201-
74). The principal accomplishment at
Maragha was the Zij-i ilkhani, or
Ilkhanic Tables. 2
A principal source of our information
about the astronomical activity at
Samarkand is a letter of one Ghiyath al-

Din Jamshid al-Kashi (d. 1429), which
is available in Turkish and English (see
Sayili 1960). This letter, originally in
Persian, was written in 1421 or 1422.
From it we deduce that serious
astronomical activity began in
Samarkand in 1408-10, and that the
construction of Ulugh Beg’s observatory
was begun in 1420. Among the
astronomers known to have been active at
Samarkand, we know only a few by
name, but according to al-Kashi there
were sixty or seventy scholars at the
madrasa who were well enough versed in
mathematics to participate in some
capacity in the astronomical observations
and/or seminars.
The observations were carried out
systematically from 1420 to 1437. While
observatories today are expected to carry
on indefinitely, this was not the case in
olden times. Rather, observations were
carried out, for example, to update tables

of planetary motions in order to predict
their future positions. al-Kashi tells us
(see Sayili 1960, p.106):
As to the inquiry of those who ask why
observations are not completed in one
year but require ten or fifteen years, the
situation is such that there are certain
conditions suited to the determination of
matters pertaining to the planets, and it is
necessary to observe them when these
conditions obtain. It is necessary, e.g., to
have two eclipses in both of which the
eclipsed parts are equal and to the same
side, and both these eclipses have to take
place near the same node. Likewise,
another pair of eclipses conforming to
other specifications is needed, and still
other cases of a similar nature are
required. It is necessary to observe
Mercury at a time when it is at its
maximum morning elongation and once
at its maximum evening elongation, with
the addition of certain other conditions,

and a similar situation exists for the
other planets.
Now, all these circumstances do not
obtain within a single year, so that
observations cannot be made in one year.
It is necessary to wait until the required
circumstances obtain and then if there is
cloud at the awaited time, the
opportunity will be lost and gone for
another year or two until the like of it
occurs once more. In this manner there is
need for ten or fifteen years.
One might add that because it takes
Saturn 29 years to return to the same
position amongst the stars (that being its
period of revolution about the Sun), a
period of 29 years might have been the
projected length of the Samarkand
program of observations. A number of
instruments were used for the observations
of the planets and for determining the
relative positions of the stars. 3 The

largest instrument in Samarkand was the
so-called Fakhri sextant.
It was a 60-degree stone arc mounted on
the north-south meridian line. Such an
instrument was used to determine the
transit altitudes of stars (i.e. their
maximum angular distances above the
horizon). From the most southern and
northern positions of the Sun, observed
over the course of a year, one can easily
determine the obliquity of the ecliptic
(i.e. the tilt of the Earth’s axis of rotation
with respect to the plane of its orbit.) The
mean of these extrema, or the meridian
altitude of the Sun at the moment of the
vernal or autumnal equinox allows one
(by definition) to determine one’s latitude.
4
According to Ulugh Beg the obliquity of
the ecliptic was 23 degrees 30′ 17″
(differing by only 32″ from the true value
for his time). His value for the latitude of
Samarkand was 39 degrees 37′ 33″. Now,

to the reader unaccustomed to
astronomical topics, these might seem like
just numbers, the accuracy of which may
mean nothing. The most interesting thing
about the Fakhri sextant in Samarkand
was that its radius was 40 meters! (This is
very nearly equal to the height of the
dome of the 200-inch reflector at
Palomar Mountain, California.)
The Fakhri sextant was by far the largest
meridian instrument ever built. It could
achieve a resolution of a several seconds
of arc — on the order of a six-hundredth
of a degree, or the diameter of an
American penny at a distance of more
than half a kilometer. Because the Fakhri
sextant was an arc fixed on the meridian,
it could only be used for determining the
declinations of celestial bodies. (This
being before the invention of accurate
clocks, it could not be used for the
determinations of relative right
ascensions.)

Because it was a 60-degree arc, it could
not be used to observe stars along the full
north-south meridian. Thus, it could not
be used, say, to determine the angular
separations of pairs of stars, or for
observing stars near the northern or
southern horizons. Consequently, other
observational instruments were used at
Samarkand, among them parallactical
lineals and equinoctial and solstitial
armillary spheres. These were made of
metal and wood and were on the order of
1 meter in size. Hand held astrolabes are
not to be included in this list, because
they were “star finders” and they were
used for rough time determination, rather
than for the accurate determination of
stellar or planetary positions.
Typically, two people were required to
make individual observations at any
given time. At Samarkand it was the
practice for a larger number of people to
discuss the results. In modern terms, this

is like peer review, the purpose of which
is to eliminate sources of error and to
ensure the health of the observational
program. Ulugh Beg himself has allowed
that in scientific questions there should
be no agreeing until the matter is
thoroughly understood and that people
should not pretend to understand in
order to be pleasing. Occasionally, when
someone assented to His Majesty’s view out
of submission to his authority, His
Majesty reprimanded him by saying ‘you
are imputing ignorance to me.’ He also
poses a false question, so that if anyone
accepts it out of politeness he will
reintroduce the matter and put the man
to shame. 5
The foreword to Ulugh Beg’s Zij contains
four parts: 1) the chronology, describing
various systems of time reckoning; 2)
practical astronomy (how observations are
made and used); 3) the apparent motions
of the Sun, Moon, and planets, based on a

geocentric system of the universe; and 4)
astrology. Besides the tables of motions of
the Sun, Moon, and planets,Ulugh Beg’s
Zij was significant for its catalogue of
about 1000 stars, giving their names and
ecliptic coordinates. In an appendix to
this paper I give a list of published works
that contain all or part of Ulugh Beg’s Zij.
6 In Flamsteed’s Historia Coelestis
Britannica (1725) and Baily’s 1843
treatise we can directly compare Ulugh
Beg’s positions with those of Ptolemy,
Tycho Brahe, and others. With modern
stellar positions, proper motions, and an
accurate treatment of precession, it would
be interesting to make a statistical
analysis of, say, the 100 brightest stars, to
see how these catalogues compare as to
average accuracy. 7
In The Observatory in Islam Sayili
concludes (pp. 391, 393) by stating:
The observatory as an organized and
specialized institution was born in Islam;

it went through very important stages of
evolution within Islam itself; it passed on
in a rather highly developed state to
Europe, and this was followed, shortly
afterwards, by the creation of modern
observatories of Europe, in an unbroken
process of evolution superposing upon the
traditions borrowed from Eastern
Islam…The question is of significance…in
the case of the Samarqand Observatory
because it appears as probably the most
important Islamic observatory from the
standpoint of influences exerted upon
Europe.
I can accept the first half of Sayili’s
perspective. The astronomical programs
carried out at Baghdad (9th century),
Cordova (10th century), Cairo (10th to
12th centuries), Toledo (11th century),
Castile (under the Christian King Alfonso
X; 13th century), Maragha (13th
century), and at Samarkand (15th
century) were far more extensive than

anything carried out by the ancient
Greeks, with the possible exception of
Hipparchus. The Arabs honored learning
and kept alive the study of astronomy by
preserving Ptolemy’s Almagest and adding
to its mathematical formulation.
The Ma’munic, Hakemite, Toledan,
Ilkhanic and Alphonsine Tables, along
with the tables contained in Ulugh Beg’s
Zij have come down to us because
scholars knew they were important. But
the influence of the Samarkand
Observatory on European astronomy was
more indirect than direct. While copies of
Ulugh Beg’s Zij existed in various
libraries such as Oxford and Paris not
long after its composition (see Razvi
1985), it only became known in Europe
in the mid-17th century, nearly five
decades after the publication of Tycho
Brahe’s much more accurate data (see
appendix to this paper).

If the activities in Samarkand influenced
European ones, why does Ulugh Beg only
get cursory mention (on pp. 328 and 347,
but not in the index) of Dreyer’s classic
1890 biography of Tycho Brahe? In
Thoren’s even more authoritative 1990
biography of Tycho there is no mention of
Ulugh Beg at all. It was work such as
Tycho’s, not Ulugh Beg’s, that led in turn
to the efforts at Greenwich (founded
1675), Pulkovo (founded 1839), and the
United States Naval Observatory (founded
1844), among other institutions, and
these modern, national, facilities did not
need or use Ulugh Beg’s work as a
fundamental component of the
construction of accurate star catalogues.
Yet, to be fair, astronomers and historians
have found many uses for ancient and
medieval observations, such as studies of
the spin down rate of the Earth, studies of
the motion of the Moon and planets, and
the dating of historical events. Ulugh Beg’s

observations being the best of their
century allow them to stand as a
permanent observational archive for our
benefit. For example, Shcheglov (1977)
has recently used information from the
modern excavation of Ulugh Beg’s large
meridian instrument for a study of
continental drift.
The most direct influence of the
Samarkand Observatory was on the
construction of the five observatories, or
Jantar Mantars, built by Maharajah Jai
Singh (1686-1743) in India. Jai Singh
was a Hindu prince in the court of a
Muslim Mogul emperor. These
observatories were built at New Delhi,
Ujjain, Mathura, Varanasi, and Jaipur.
The largest instrument was 27 meters
high. For more information see Kaye
(1918), Mayer (1979), Sharma (1987),
and Bedding (1991).
While recognition of Ulugh Beg’s
contributions to astronomy was delayed,

an extensive body of information now
exists on the activity of his observatory in
Samarkand. 8 We now know that at the
time Ulugh Beg’s observatory flourished it
was carrying out the most advanced
observations and analysis being done
anywhere. In the 1420’s and 1430’s
Samarkand was the astronomical capital
of the world. As such it is deserving of
further study.
A model of the huge quadrant
Notes:

1. Member, International Astronomical
Union, Commission 41 (History of
Astronomy).
2. A zij is an astronomical treatise that
usually contains tables for calculating the
positions of the Sun, Moon, and planets. It
might also contain a star catalogue.
3. For a discussion of the astronomical
instrumentation of the Arabs, see Sedillot
(1841), Repsold (1908), and Krisciunas
(1988,chapter 2). Note that the telescope
was only first used for astronomical
purposes in 1609.
4. Strictly speaking, one must also account
for atmospheric refraction. For a review of
astronomical coordinate systems see
Krisciunas (1988, chapter 1).
5. Sayili (1960, pp. 109-110).
6. The appendix is largely based on
information found in Shcheglov (1968;
1979) and in the National Union Catalog

Pre-1956 Imprints. I thank Paul Luther
for additional information.
7. Vogt (1925) found 22′ for the average
error of 122 Ptolemaic celestial latitudes.
The best of Tycho’s stellar positional
measures are good to 1′. See Dreyer (1890,
pp.387-8), Wesley (1978), and Thoren
(1990, pp. 287-299, and references
therein).
8. See Kary-Niiazov (1967) and
Sirazhdinov (1979).

The trench with the lower section of the
meridian arc
References and Further Readings
Barthold, W. W., Ulugh Beg und seine
Zeit. Abhandlungen fur die Kunde des
Morganlandes 21, No. 1, 1935.
Bedding, James, “Playground for the
stars: The Jantar Mantars, Astronomical

Observatories in India,” New Scientist, 31
August 1991, p. 49.
Dreyer, J. L. E., Tycho Brahe: A Picture of
Scientific Life and Work in the Sixteenth
Century (Gloucester, Mass.:Peter Smith),
1977 reprint. (Original edition published
by Adam & Charles Black, Edinburgh,
1890)
Kar[y]-N[i]iazov, T. N., “Ulugh Beg”, in
Dictionary of Scientific Biography 13, pp.
535-537
Kary-Niiazov, T. N., Astronomicheskaia
shkola Ulugbeka, (Tashkent), 1967
Kaye, G. R., The Astronomical
Observatories of Jai Singh, (Janpath, New
Delhi: Archaeological Survey of India),
reprint of 1918 edition
Krisciunas, Kevin, Astronomical Centers
of the World (Cambridge: Cambridge Univ.
Press), 1988

Mayer, Ben, “Touring the Jai Singh
Observatories,” Sky and Telescope 58, No.
1, July 1979, pp. 6-10
Razvi, Abbas, “The Observatory at
Samarqand (Marsad-e-Ulugh Beg, 15th
C),” Central Asia, No. 17, 1985, pp. 97-
150
Repsold, Johann A., Zur Geschichte der
Astronomischen Mess-werkzeuge von
Purbach bis Reichenbach (1450 bis
1830) (Leipzig: Wilhelm Engelmann),
1908. I have a rough (unpublished)
English translation, which I would be
happy to provide anyone, of the first six
sections of this work, covering the
astronomical instrumentation of the
ancient Greeks, the Arabs, Purbach,
Regiomontanus, Copernicus, Apian,
Wilhelm IV of Hesse-Cassel, and Tycho
Brahe
Sarton, George, Introduction to the History
of Science (Baltimore: Williams &

Wilkins), 1948, vol. 3, pp. 1120, 1467-
1474
Sayili, Aydin, Ulug Bey Ve
Semerkanddeki Ilim Faaliyeti Hakkinda
Giyasuddin-i Kasi’nin Mektubu (Ghiyath
al Din al Kashi’s Letter on Ulugh Bey and
the Scientific Activity in Samarqand)
(Ankara: Turk Tarih Kurumu Basimevi),
1960. In note 1, pp. 32-33 of this work it
is stated that another English translation
was published by E. S. Kennedy
(Orientalia 29, 1960, pp. 191-213),
which differs in many particulars, and
that the Persian text of the letter was
published twice before that.
Sayili, Aydin, The Observatory in Islam
and its Place in the General History of
the Observatory (New York: Arno Press),
1981 reprint (Original edition published
by Turk Tarih Kurumu Basimevi,
Ankara, 1960)

Sedillot, L. [P. E. A.], Memoire sur les
instruments astron. des Arabes, Paris,
1841
Sharma, V. N., “The Astronomical Efforts
of Sawai Jai Singh,” in G. Swarup [et al.],
eds., History of Oriental Astronomy
(Cambridge: Cambridge Univ. Press),
1987, pp. 233-240
Sh[ch]eglov, V. P., Jan Hevelius: The Star
Atlas (Tashkent: “Fan” Press), 1968
Shcheglov, V. P., “Astronomical azimuths
of terrestrial objects as indicators of the
rotational motions of the continental
blocks,” Soviet Astronomy 21, No. 4,
July-August 1977, pp. 499-502
Shcheglov, V. P., “Rasprostranenie <> v
evropeiskoi pechati,” in Sirazhdinov
(1979, see below), pp. 143-151
Sirazhdinov, S. KH., ed., Iz istorii nauki
epokhi Ulugbeka, (Tashkent: Academy of
Sciences of the Uzbek SSR), 1979

Thoren, Victor E., The Lord of Uraniborg:
A Biography of Tycho Brahe (Cambridge:
Cambridge University Press), 1990
Vogt, H., “Versuch einer Wiederherstellung
von Hipparchs Fixsternverzeichnis,”
Astronomische Nachrichten, No. 5354-55
(1925):23
Wesley, Walter, “The accuracy of Tycho
Brahe’s instruments,” Journal for the
History of Astronomy 9 (1978), pp.42-53
Jade dragon cup that once belonged to Ulugh
Beg
Editions Containing All or Part of Ulugh
Beg’s Zij
1648. John Greaves (1602-1652). Quibus
accesserunt, Insigniorum aliquot
Stellarum Longitudines, et Latitudines,
Ex Astronomicis Observationibus Ulug
Beigi, Tamerlani Magni Nepotis. Oxoniae.

Contains latitudes and longitudes of [98]
stars
1648. John Greaves (1602-1652). Binae
Tabulae Geographicae, una Nassir Eddini
Persae, altera Vlug Beigi Tatari: Opera et
Studio J. Gravii. Lugduni, Batavorum.
Geographical tables of the Zij
1648. John Bainbridge (1582-1643).
Canicularia. Una cum demonstratione
ortus Sirii heliaci, pro parallelo
inferioris Aegypti. Auctore Iohanne
Gravio. Quibus accesserunt, insigniorum
aliquot stellarum longitudines, et
latitudines, ex astronomicis
observationibus Vlug Beigi. Oxoniae, H.
Hall. The citation in the U. S. Naval
Observatory copy states that Greaves added
the catalogue of 98 Ulugh Beg stars to the
Bainbridge treatise
1650. John Greaves (1602-1652).
Epochae Celebriores, Astronomis,
Historicis, Chronologis, Chataiorum,
Syro-Graecorum Arabum, Persarum,

Chorasmiorum usitatae (Arabice et
Latine): Ex traditione Ulugi Beigi; eas
primus publicavit, recensuit, et
Commentarius illustravit Johannes
Gravius. Londini, J. Flesher. Latin and
Persian on opposite pages. That part of the
Zij dealing with chronology
1652. John Greaves (1602-1652). Binae
Tabulae Geographicae, una Nassir Eddini
Persae, altera Vlug Beigi Tatari: Opera et
Studio J. Gravii nunc primum
publicatae. Londini, Typis Jacobi Flesher:
prostant apud Cornelium Bee. 2nd edition
of geographical tables
1665. Thomas Hyde (1636-1703).
Tabulae long. ac lat. stellarum fixarum,
ex observatione Ulugh Beighi, Tamerlanis
Magni Nepotis, Regionum ultra citraque
Gjihun (i. Oxum) Principis potentissimi.
Ex tribus invicem collatis MSS. Persicis
jam primum Luce ac Latiodonavit, &
commentariis illustravit, Thomas Hyde. In
calce libriaccesserunt Mohammedis

Tizini tabulae declinationum &
rectarium ascensionum. Additur demum
Elenchus Nominum Stellarum. Oxonii:
Typis Henrici Hall, sumptibus authoris.
Tables in Latin and Persian for 1018
stars of which about 700 were based
exclusively on Ulugh Beg and the balance
were reduced from Ptolemy in one or both
coordinates. Hyde appears to have worked
totally independent of Greaves
1690. Johannes Hevelius (1611-1687).
Prodromus Astronomiae. Danzig. Contains
a comparison of data in Ulugh Beg’s tables
with other star catalogues known at that
time — those of Ptolemy, Tycho Brahe,
Giambattista Riccioli, Wilhelm IV
(Landgrave of Hesse-Cassel), and Hevelius
1698-1712. Geographiae veteris scriptores
graeci minores. Cum interpretatione
latina, dissertationibus, ac
annotationibus… Oxoniae, e Theatro
Sheldoniano. A work containing Ulugh
Beg’s geographical tables

1725. John Flamsteed (1646-1719).
Historia Coelestis Britannica. London, 3
vols. Includes Ulugh Beg’s catalogue, along
with those of Ptolemy, Tycho Brahe,
Wilhelm IV, and Hevelius
1767. Gregory Sharpe. Syntagma
dissertationum quas olim auctor
doctissimus Thomas Hyde, S. T. P.
separatim edidit. Accesserunt nonnulla
ejusdem opuscula hactenus inedita, &c.
&c. Omnia diligenter recognita a Gregorio
Sharpe, LL.D. Reg. Maj. a sacris. Templi
Magistro S.S.R. et A.S. Oxonii. Reprint,
with corrections, of Hyde’s 1665 work on
the Zij, in a 2 vol. collection of Hyde’s
work
1807. Duo pinakez geographikoi, d men
Nassir ‘Eddinou Persou, d de Ouloug
Mpei Tatarou. ‘Epimeleia kai opoudh
Dhmhtriou ‘Alexandridou … Kata thn en
‘Oxonia ekdosin tou sophou Grauiou. ‘En
Biennh thz Austriaz, ek thz tupographiaz
‘A. Sxmidiou. Ulugh Beg’s geographical

tables published in Vienna in a Greek-
language edition
1843. Francis Baily (1774-1844). “The
Catalogues of Ptolemy, Ulugh Beigh,
Tycho Brahe, Halley and Hevelius,
Deduced From the Best Authorities, With
Various Notes and Corrections,” Memoires
of the Royal Astronomical Society 13, pp.
19-28, 79-125, London. Reprinted from
Thomas Hyde’s translation, as edited by
Gregory Sharpe in 1767
1839. L. P. E. A. Sedillot (1808-1875).
Tables astronomiques d’Oloug Beg,
commentees et publiees avec le texte en
regard, Tome I, 1 fascicule, Paris. A very
rare work, but referenced in the
Bibliographie generale de l’astronomie
jusqu’en 1880, by J. C. Houzeau and A.
Lancaster (Brussels, 3 vols. 1887-9;
reprinted London, 1964)
1847. L. P. E. A. Sedillot (1808-1875).
Prolegomenes des Tables astronomiques
d’Oloug Beg, publiees avec Notes et

Variantes, et precedes d’une Introduction.
Paris: F. Didot
1853. L. P. E. A. Sedillot (1808-1875).
Prolegomenes des Tables astronomiques
d’Oloug Beg, traduction et commentaire.
Paris
1917. Edward Ball Knobel (1841-1930).
Ulugh Beg’s Catalogue of Stars, Revised
from all Persian Manuscripts Existing in
Great Britain, with a Vocabulary of
Persian and Arabic Words. Washington,
D. C.: The Carnegie Institute of
Washington
http://vlib.iue.it/carrie/texts/carrie_books
/paksoy-2/cam6.html

Ulugh Beg's headstone at the foot of
Timur's in the Gur-e-Amir
=================================
Ulugh Beg (Mīrzā Muhammad Tāraghay
bin Shāhrukh) ‫بیگ‬ ‫الغ‬
Mīrzā Muhammad Tāraghay bin
Shāhrukh (Chagatai: ‫رخ‬ ‫شاہ‬ ‫بن‬ ‫طارق‬ ‫محمد‬ ‫میرزا‬,
Persian: ‫رخ‬ ‫شاہ‬ ‫بن‬ ‫تراغای‬ ‫محمد‬ ‫میرزا‬) better known
as Ulugh Beg (‫بیگ‬ ‫الغ‬) (March 22, 1394 in
Sultaniyeh, Persia – October 27, 1449,
Samarkand) was a Timurid ruler as well
as an astronomer, mathematician and
sultan. His father, Shahrukh had five
sons, but only Ulugh Beg, who was an
excellent mathematician but an
incapable ruler, was left to succeed his
father.
His commonly known name is not truly a
personal name, but rather a moniker,
which can be loosely translated as “Great
Ruler” or “Patriarch Ruler” and was the

Turkic equivalent of Timur’s Perso-
Arabic title Amīr-e Kabīr.
He ruled Uzbekistan, Tajikistan,
Turkmenistan, Kyrgyzstan, southern
Kazakhstan and most of Afghanistan for
almost half a century from 1411 to 1449.
He was a grandson of the great conqueror,
Timur (Tamerlane) (1336–1405), and
the oldest son of Shah Rukh, both of
whom came from the Turkicized Barlas
tribe of Transoxiana (now Uzbekistan).
His mother was a noblewoman named
Goharshad, daughter of the representative
Turkic of tribal aristocracy Giyasitdin
Tarhan. Ulugh Beg was born in
Sultaniyeh in Persia during Timur’s
invasion. As a child he wandered
through a substantial part of the Middle
East and India as his grandfather
expanded his conquests in those areas.
After Timur’s death, however, and the
accession of Ulugh Beg’s father to much of
the Timurid Empire, he settled in

Samarkand, which had been Timur’s
capital. After Shah Rukh moved the
capital to Herat (in modern Afghanistan),
sixteen-year-old
Ulugh Beg became his governor in
Samarkand in 1409. In 1411, he became
the sovereign ruler of the whole
Mavarannahr khanate. Ulugh Beg was
also notable for his work in astronomy-
related mathematics, such as trigonometry
and spherical geometry.
He built the great Ulugh Beg Observatory
in Samarkand between 1424 and 1429.
It was considered by scholars to have been
one of the finest observatories in the
Islamic world at the time and the largest
in Central Asia. He built the Ulugh Beg
Madrasah (1417–1420) in Samarkand
and Bukhara, transforming the cities into
cultural centers of learning in Central
Asia.
He was also a mathematician of the 15th
century — albeit his mental aptitude was

perseverance rather than any unusual
endowment of intellect.
His observatory is situated in Samarkand
which is in Uzbekistan.
https://www.geni.com/people/Ulugh-Beg-
Mīrzā-Muhammad-Tāraghay-bin-
Shāhrukh-6000000040320078561/ ‫الغ‬
-
‫ب‬
‫ی‬
‫گ‬
Ulugh beg Medresa
=============================

Ulugh Beg – Astronomer
22 March 2015
On March 22, 1394, Mongolian
astronomer, mathematician and sultan
Mīrzā Muhammad Tāraghay bin
Shāhrukh, better known as Ulugh Beg
was (probably) born. Although the only
important Mongol scientist, he was the
greatest astronomer of his time. Pursuing
this interest he built an observatory at
Samarkand. In his observations he
discovered a number of errors in the
computations of the 2nd-century
Alexandrian astronomer Ptolemy, whose
figures were still being used.
Ulugh Beg was the grandson of the
conqueror Timur. After Timur’s death, the
empire was disputed among his sons
including Skah Rukh, Ulugh Beg’s father.
Starting from 1407, he controlled a great
part of the empire including Iran and
Turkistan regaining control of
Samarkand. Two years later, Shah Rukh

decided to make Herat in Khorasan his
new capital and made it a center of trade
and culture while Samarkand was given
to Ulugh Beg, who was highly interested
in making the city a cultural centre
instead of dealing with politics and the
military.
It is believed that already in his early
years, Ulugh Beg was interested in science,
especially astronomy. He visited the
remains of Maragha Observatory in his
younger years. However, Ulugh Beg also
never neglected the arts, writing poetry
himself and studying history. He built a
center for higher education, especially
mathematics, which was completed in
1420. Ulugh Beg began to appoint the best
scientists he could find to positions there
as lecturers.
Al-Kashi became one of the leading
figures of the scientific life of Samarkand
and in his letters, he praised the
mathematical achievements of Ulugh Beg,

who led scientific meetings where
problems in astronomy were freely
discussed. Soon, Ulugh Beg started to built
an astronomy at Samarkand and the
construction works probably began in
1428. The observatory was over 35 meters
high and 50 meters in diameter.
The scientists working at the observatory
were able to find methods for giving
accurate approximate solutions of cubic
equations and work with the binomial
theorem. Also, Ulugh Beg’s accurate tables
of sines and tangents correct to eight
decimal places were established and
formulae of spherical trigonometry were
found. Further, Ulugh Beg’s Catalogue of
the stars, the first comprehensive stellar
catalogue since that of Ptolemy, counts to
one of their greatest achievements.
The star catalogue, the Zij-i Sultani, was
published in 1437 and gives the positions
of almost 1000 stars. The catalogue was
accomplished by Ulugh Beg himself, al-

Kashi, and Qadi Zada. The work
contained tables of observations made at
the Observatory, calendar calculations
and results in trigonometry. Further,
several mistakes in the calculations of
Ptolemy were found and with the help of
the new findings, Ulugh Beg was able to
calculate the length of the year as 365
days 5 hours 49 minutes 15 seconds.
Unfortunately, after the death of Ulugh
Beg’s father in 1447, he could not retain
power and was put to death. In 1941, his
tomb was discovered in the mausoleum
built by Timur in Samarkand.
http://scihi.org/ulugh-beg-astronomer/

Ulugh Beg Madrasa
================================
Ulugh Beg
Born: 1393 in Soltaniyeh, Timurid,
Persia (now Iran)
Died: 27 October 1449 in Samarkand,
Timurid empire
By: J. J. O’Connor and E. F. Robertson
Ulugh Beg was the grandson of the
conqueror Timur, who is often known as
Tamerlane (from Timur-I-Leng meaning
Timur the Lame, a title of contempt used

by his Persian enemies). Although in this
archive we are primarily interested in
Ulugh Beg’s achievements in mathematics
and astronomy, we need to examine the
history of the area since it had such a
major impact on Ulugh Beg’s life.
Timur, Ulugh Beg’s grandfather, came
from the Turkic Barlas tribe which was a
Mongol tribe that was living in
Transoxania, today essentially
Uzbekistan. He united several Turko-
Mongol tribes under his leadership and
set out on a conquest, with his armies of
mounted archers, of the area now
occupied by Iran, Iraq, and eastern
Turkey.
Shortly after his grandson Ulugh Beg was
born, Timur invaded India and by 1399
he had taken control of Delhi. Timur
continued his conquests by extending his
empire to the west from 1399 to 1402,
winning victories over the Egyptian
Mamluks in Syria and the Ottomans in a

battle near Ankara. Timur died in 1405
leading his armies into China.
After Timur’s death his empire was
disputed among his sons. Ulugh Beg’s
father Shah Rukh was the fourth son of
Timur and, by 1407, he had gained
overall control of most of the empire,
including Iran and Turkistan regaining
control of Samarkand. Samarkand had
been the capital of Timur’s empire but,
although his grandson Ulugh Beg had
been brought up at Timur’s court, he was
seldom in that city. When Timur was not
on one of his military campaigns he
moved with his army from place to place
and his court, including his grandson
Ulugh Beg, travelled with him.
In 1409 Shah Rukh decided to make
Herat in Khorasan (today in western
Afghanistan) his new capital. Shah Rukh
ruled there making it a trading and
cultural centre. He founded a library
there and became a patron of the arts.

However Shah Rukh did not give up
Samarkand, rather he decided to give it
to his son Ulugh Beg who was more
interested in making the city a cultural
centre than he was in politics or military
conquest. Although Ulugh Beg was only
sixteen years old when his father put him
in control of Samarkand, he became his
father’s deputy and he became ruler of
the Mawaraunnahr region.
Ulugh Beg was primarily a scientist, in
particular a mathematician and an
astronomer. However, he certainly did not
neglect the arts, writing poetry and
history and studying the Qur’an. In 1417,
to push forward the study of astronomy,
Ulugh Beg began building a madrasah
which is a centre for higher education.
The madrasah, fronting the Rigestan
Square in Samarkand, was completed in
1420 and Ulugh Beg then began to
appoint the best scientists he could find to
positions there as lecturers.

Ulugh Beg invited al-Kashi to join his
madrasah in Samarkand, as well as
around sixty other scientists including
Qadi Zada. There is little doubt that,
other than Ulugh Beg himself, al-Kashi
was the leading astronomer and
mathematician at Samarkand. Letters
which al-Kashi wrote to his father have
survived. These were written from
Samarkand and give a wonderful
description of the scientific life there. The
contents of one of these letters have only
recently been published.
In the letters al-Kashi praises the
mathematical abilities of Ulugh Beg but
of the other scientists in Samarkand, only
Qadi Zada earned his respect. Ulugh Beg
led scientific meetings where problems in
astronomy were freely discussed. Usually
these problems were too difficult for all
except al-Kashi and the letters confirm
that al-Kashi was the closest collaborator

of Ulugh Beg at his madrasah in
Samarkand.
In addition to the madrasah, Ulugh Beg
built an observatory at Samarkand, the
construction of this beginning in 1428.
The Observatory, which was circular in
shape, had three levels. It was over 50
metres in diameter and 35 metres high.
The director of the Observatory was Ali-
Kudschi, a Muslim astronomer. Al-Kashi
and other mathematicians and
astronomers appointed to the madrasah
also worked at Ulugh Beg’s Observatory.
Among the instruments specially
constructed for the Observatory was a
quadrant so large that part of the ground
had to be removed to allow it to fit in the
Observatory. There was also a marble
sextant, a triquetram and an armillary
sphere. The achievements of the scientists
at the Observatory, working there under
Ulugh Beg’s direction and in
collaboration with him, are discussed in

detail in. This excellent book records the
main achievements which include the
following: methods for giving accurate
approximate solutions of cubic equations;
work with the binomial theorem; Ulugh
Beg’s accurate tables of sines and tangents
correct to eight decimal places; formulae
of spherical trigonometry; and of
particular importance, Ulugh Beg’s
Catalogue of the stars, the first
comprehensive stellar catalogue since that
of Ptolemy.
This star catalogue, the Zij-i Sultani, set
the standard for such works up to the
seventeenth century. Published in 1437,
it gives the positions of 992 stars. The
catalogue was the results of a combined
effort by a number of people working at
the Observatory including Ulugh Beg, al-
Kashi, and Qadi Zada. As well as tables
of observations made at the Observatory,
the work contained calendar calculations
and results in trigonometry.

The trigonometric results include tables of
sines and tangents given at 1° intervals.
These tables display a high degree of
accuracy, being correct to at least 8
decimal places. The calculation is built
on an accurate determination of sin 1°
which Ulugh Beg solved by showing it to
be the solution of a cubic equation which
he then solved by numerical methods. He
obtained
sin 1° = 0.017452406437283571
The correct approximation is
sin 1° = 0.017452406437283512820
which shows the remarkable accuracy
which Ulugh Beg achieved.
Observations made at the Observatory
brought to light a number of errors in the
computations of Ptolemy which had been
accepted without question up to that time.
Data from his Observatory allowed Ulugh
Beg to calculate the length of the year as
365 days 5 hours 49 minutes 15 seconds,

a fairly accurate value. He produced data
relating to the Sun, the Moon and the
planets. His data for the movements of the
planets over a year is, like so much of his
work, very accurate:
… the difference between Ulugh Beg’s data
and that of modern times relating to
[Saturn, Jupiter, Mars, Venus] falls
within the limits of two to five seconds.
Ulugh Beg’s politics were not up to his
science and, after his father’s death in
1447, he was unable to retain power
despite being an only son. He was
eventually put to death at Samarkand at
the instigation of his own son ‘Abd al-
Latif. His tomb was discovered in 1941 in
the mausoleum built by Timur in
Samarkand. It was discovered that Ulugh
Beg had been buried in his clothes which
is known to indicate that he was
considered a martyr. The injuries
inflicted on him were evident when his
body was examined:

… the third cervical vertebra was severed
by a sharp instrument in such a way that
the main portion of the body and an arc
of that vertebra were cut cleanly; the
blow, struck from the left, also cut
through the right corner of the lower jaw
and its lower edge.
and.ac.uk/Biographies/Ulugh_Beg.html
Ulugh Beg Madrasah
===========================
Ulugh Beg
Ulugh Beg was a Timurid ruler as well as
an astronomer, mathematician. His
primary interest was in the sciences and
intellectual matters. He built an
observatory at Samarkand. In his

observations he discovered a number of
errors in the computations of the 2nd-
century Alexandrian astronomer Ptolemy.
Ulugh Beg was also notable for his work
in astronomy-related mathematics, such
as trigonometry and spherical geometry.
in Samarkand, which was considered by
scholars to have been one of the finest
observatories in the Islamic world at the
time and the largest in Central Asia….
Muhammad Taraghāy ibn Shāhrukh ibn
Tīmūr, known as Ulugh
Beg Born in Sultāniyya (Iran) on 22
March 1394
Died near Samarqand (Uzbekistan) on 27
October 1449
Muhammad Taraghāy ibn Shāhrukh ibn
Tīmūr better known as Ulugh Beg
(Sultāniyya (Iran) on 22 March 1394
and died near Samarqand (Uzbekistan)
on 27 October 1449) was a Timurid ruler

as well as an astronomer, mathematician.
Ulūgh Beg was the grandson of the Asian
conqueror Timur (Tamerlane). His
primary interest was in the sciences and
intellectual matters. Under his brief rule
the Timurid dynasty reached its cultural
peak. His father, Shāh Rokh, captured
the city of Samarkand and gave it to
Ulūgh Beg, who made it a centre of
Muslim culture. There he wrote poetry
and history and studied the Qur?ān. His
greatest interest was astronomy, and he
built an observatory (begun in 1428) at
Samarkand. In his observations he
discovered a number of errors in the
computations of the 2nd-century
Alexandrian astronomer Ptolemy, whose
figures were still being used.
Ulugh Beg was also notable for his work
in astronomy-related mathematics, such
as trigonometry and spherical geometry.
in Samarkand, which was considered by

scholars to have been one of the finest
observatories in the Islamic world at the
time and the largest in Central Asia. He
also build the Ulugh Beg Madrasah
(1417–1420) in Samarkand and
Bukhara, transforming the cities into
cultural center of learning in Central
Asia.
In a long and detailed article on
Astronomical Observatories in the
Classical Islamic Culture, FSTC Research
Team devoted a section to The Legacy of
Ulugh Beg that we reproduce to celebrate
the anniversary of this great scholar.
The Legacy of Ulugh Beg
In a noteworthy article by Kevin
Krisciunas (University of Notre Dame,
Department of Physics) on The Legacy of
Ulugh Beg, the author presents an outline
on the subject of Muslim observatories and
especially the work performed in
Samarqand observatory.

Krisciunas reminds us that Ulugh Beg is
to be remembered not for his princely
role, but for his role as patron of
astronomy, an astronomer and observatory
builder. His distinction was that he was
one of the first to advocate and build
permanently mounted astronomical
instruments. The importance of his
observatory is further enhanced by the
large number of astronomers, between
sixty and seventy, involved in observation
and seminars. Of crucial importance, too,
is that observations were carried on a
systematic basis forlengthy periods of
time, as from 1420 to 1437. The reason,
as Krisciunas makes clear, why
observations are not completed in one
year but instead require ten or fifteen
years, is:
“The situation is such that there are
certain conditions suited to the
determination of matters pertaining to the
planets, and it is necessary to observe

them when these conditions obtain. It is
necessary, e.g., to have two eclipses in both
of which the eclipsed parts are equal and
to the same side, and both these eclipses
have to take place near the same node.
Likewise, another pair of eclipses
conforming to other specifications is
needed, and still other cases of a similar
nature are required. It is necessary to
observe Mercury at a time when it is at its
maximum morning elongation and once
at its maximum evening elongation, with
the addition of certain other conditions,
and a similar situation exists for the
other planets.
“Now, all these circumstances do not
obtain within a single year, so that
observations cannot be made in one year.
I is necessary to wait until the required
circumstances obtain and then if there is
cloud at the awaited time, the
opportunity will be lost and gone for
another year or two until the like of it

occurs once more. In this manner, there is
a need for ten or fifteen years. One might
add that because it takes Saturn 29 years
to return to the same position amongst the
stars (that being its period of revolution
about the Sun), a period of 29 years
might have been the projected length of
the Samarkand programme of
observations.”
In his article, Krisciunas, although
recognising the crucial role of Islamic
observation, still finds sources of
disagreement with the notion that the
Samarqand observatory exerted decisive
influence on Europe. Actually, the legacy
of this scientific institution was indeed
not transmitted to the West, where a
thriving scientific tradition was being
developed as a result of earlier contacts
with Arabic science. It remains true,
however, that the work of Ulugh Beg and
his colleagues had an important impact
on another Islamic team of scholars, those

who worked in Istanbul in late 16th
century under the leadership of Taqi al-
Din ibn Ma’ruf. Now, the similarity of
Taqi al-Din’s astronomical instruments
with those of Tycho Brahe is amazing,
and should stand as a strong evidence
that the Danish astronomer certainly
knew in a way or another of the
achievements of his Muslim colleagues, at
least in the field of astronomical
instrumentation.
“The Samarkand observatory consisted of
a monumental cylindrical building of a
height of 30 meters and a diameter of 46,
with a huge marble sextant, the “Sextant
of Fakhri”, of a radius of about 40
meters, allowing a very high precision in
the astronomical measurements during
the passage of the Sun, the Moon or the
planets along the meridian. This arch of
60° included staircases on each side to
allow the assistants carrying out the
measurements to move.”

End Notes
Kevin Krisciunas, “The Legacy of Ulugh
Beg”, Bulletin of the Association for the
Advancement of Central Asian Research,
vol. 5, no. 1, Spring 1992, pp. 3-6.
Reprinted in in Central Asian
Monuments, edited by Hasan B. Paksoy,
Istanbul: Isis Press, 1992, pp. 95-103 (for
an online version click here). See also by
the same author: “The accuracy of the
measurements in Ulugh Beg’s star
catalogue”, Bulletin of the American
Astronomical Society, vol. 24, no. 4,
1992, 1166-7; “A more complete analysis
of the errors in Ulugh Beg’s star
catalogue”, Journal for the History of
Astronomy, vol. 24, November 1993, pp.
269-280; and “Observatories”,
Encyclopedia of Astronomy and
Astrophysics, Institute of Physics
Publishing, 1999 (available on The
astrophysics preprint server: arXiv:astro-
ph/9902030.

These issues were studied by Sevim Tekeli,
The Instruments of Istanbul Observatory
(published
on http://www.MuslimHeritage.com, 8
June 2008). See also Aydin Sayili,
Observatories In Islam and Salim Aydüz,
Ottoman Contributions to Science and
Technology: Examples from Geography
and Astronomy.
https://muslimheritage.com/ulugh-beg/
Ulugh Beg observatory
==============================

Ulugh Beg and His Observatory
By Daniel C. Waugh
Ulugh Beg was the oldest son of
Shahrukh, born in the city of Sultaniyah
during his grandfather Timur’s
(Tamerlane’s) campaign in northern Iran
in 1394. At age 4 he accompanied his
grandfather as far as Kabul, on the
campaign that went on to take Delhi;
almost immediately after the Indian
campaign, he joined Tamerlane’s
campaign to the west which resulted in
the defeat of the Ottoman ruler Bayezid I
at Ankara in 1402. As Tamerlane was
preparing to invade China, he celebrated
the marriages of several of his grandsons,
among them Ulughbeg (then age 10), who
also was designated to rule over a
significant portion of Moghulistan (the
region encompassing part of the Tien
Shan Mountains and NW Xinjiang),
which, of course, was yet to be conquered.
It is likely that Ulugh Beg was one of the

princes seen by the Spanish ambassador
Clavijo when he visited Tamerlane’s court
in 1403-1404.
Tamerlane’s death in early 1405 not only
cancelled the invasion of China but
ushered in a period of civil strife in
which the young Ulugh Beg took an active
part. When his father, Shahrukh, finally
managed to regain control over
Transoxiana, he appointed Ulugh Beg as
the regent there. The latter assumed his
full responsibilities in 1411, although he
continued to be subordinate to his father,
who ruled the empire from Herat. At
Shahrukh’s death in 1447, Ulugh Beg
succeeded him, but survived only two
years as an independent ruler before
being overthrown and beheaded in 1449.
Although for a time in the mid-1420s
Ulugh Beg’s armies waged a successful war
for control of parts of Moghulistan
(including Kashgar), increasingly he
seems to have devoted himself to scholarly

pursuits and patronage of the arts. In
1417-1420 he had a large madrasa
(school) built, which still stands on the
Registan in the center of Samarkand. The
Timurid founder of the Moghul Empire
in the early sixteenth century, Babur,
describes what this complex of buildings
was like then (only the school has
survived):
Amongst Ulugh Beg’s buildings inside the
town are a college and a hospice
(khanaqah). The dome of the hospice is
very large: few so large are known
anywhere else in the world. Near these
two buildings he constructed an excellent
hot bath…; he had the pavements in this
made of all sorts of stone. There is no bath
like this in Khurasan or anywhere else
in Samarkand….To the south of the college
is his mosque, known as the “Carved
Mosque” because its ceiling and walls are
all covered with carved islimi and
pictures made of inlaid woods…

Babur goes on to describe Ulugh Beg’s
observatory and some of the splendid
gardens and pavilions that he had built,
one of them apparently decorated with
porcelain specially ordered from China.
His conscious efforts to honor his
grandfather included donation of the
huge Koran stand that can still be seen in
the Bibi Khanum Mosque and placement
of of a striking jade cenotaph above
Tamerlane’s grave in the Gur-i Amir
mausoleum. There is reason to believe
that this huge block of jade came as booty
from one of Ulugh Beg’s campaigns in
Moghulistan in the 1420s. Ulugh Beg was
laid to rest in the Gur-i Mir at the feet of
his grandfather (in the photo, Ulugh Beg’s
grave is in the foreground; Tamerlane’s
behind).
While the achievements of his reign were
many, he is probably best remembered for
his scientific contributions. The madrasa
became a major center of learning in the

Islamic world, whose influence spread
widely and lasted beyond Ulugh Beg’s
death, at which time some of the scholars
he had supported left Samarkand for
capitals such as Istanbul which promised
more stability. The first director of his
observatory was Qazizadeh Rumi, who
had in fact come to Central Asia from
Anatolia and was one of Ulugh Beg’s
teachers. Tradition has it that he is
buried the elegant double-domed tomb
constructed for him in the Shah-i Zinde
mausoleum complex at Ulugh Beg’s behest.
The tradition of Islamic science upon
which Ulugh Beg and his scholars drew
had long been valued by the rulers of
Inner Asia. For example, the famous
Mongol Emperor Khubilai Khan, staffed
his new observatory in Beijing (shown on
the left) with Muslim scientists. Muslim
scholars made important contributions in
mathematics (as is well known, our word
“algebra” and the mathematics it

embodies come from Arabic treatises). In
astronomy, they drew heavily on the
legacy of Classical Greece and Rome. One
concern of royal astronomers was with
calendars and astrological readings of
heavenly signs (the boundary between
astronomy and astrology was not clearcut
as it is today).
Underlying such “practical” applications
was serious measurement and study of the
movement of heavenly bodies; it is in this
area that Ulugh Beg made some of his
most important contributions. The
observatory built at Maragha in the late
thirteenth century for the Mongol
Ilkhanid rulers of Iran was probably the
most important direct influence on the
Samarkand observatory.
His observatory was built beginning
around 1420 on a hill to the north of
Samarkand. Since it was destroyed within
a few generations of his death, by the
twentieth century no one knew its exact

location. All that remains of the
building, now excavated by
archaeologists, are the foundations and
the lower part of the largest of its
scientific instruments, a huge “sextant.”
There is a small museum with exhibits
about Ulugh Beg and his scientific
achievements; one can contemplate there
a bust sculpted on the basis of the study
of his remains.
Babur described the building as it still
stood in the early sixteenth century:
Another of Ulugh Beg Mirza’s fine
buildings is an observatory, that is, an
instrument for writing astronomical
tables. this stands three storeys high, on
the skirt of the Kohik upland. By its
means the Mirza worked out the
Gurkhani Tables, now used all over the
world instead of earlier such
compilations….
One modern reconstruction of the
building’s appearance is shown here.

The so-called “sextant” obviously would
have extended well above the ground (as
the drawing shows) and likely was closer
to being a quadrant. As Krisciunas points
out in his interesting discussion of the
instrument, it “was by far the largest
meridian instrument ever built.”
Fragments of the curved measuring track
have survived with markings for around
20 degrees; this is about the highest point
that observations likely would have been
made. The “sextant” would have been
used to measure the angle of elevation of
major heavenly bodies, especially at the
time of the winter and summer solstices.
Light from the given body, passing
through a controlled opening, would have
shone on the curved track, which is
marked very precisely with degrees and
minutes.
“It could achieve a resolution of several
seconds of arc–on the order of a six-
hundredth of a degree, or the diameter of

an American penny at a distance of more
than half a kilometer” (Krisciunas). It is
not clear whether more than the sun and
moon could have been measured in this
fashion, since planets, for example, would
not have cast sufficient light. The
observatory was equipped with a variety
of other instruments, which probably
accounted for the largest part of its
scientific measurement. While only
written lists (not the actual instruments)
have survived, one can at least get a feel
for what some might have been like
(among them armillary spheres) from
those to be seen today atop Khubilai
Khan’s observatory in Beijing.
One of the most important measurements
carried out by Ulugh Beg’s astronomers
was the obliquity of the ecliptic. The
ecliptic is the circular path described by
the the sun in the course of a year, and
its obliquity is the angle at which it cuts
the equator. Establishing this precisely is

important for a variety of other
astronomical measurements and
calendrical calculations. The astronomers
in the classical world had errors on the
order of 7′-10′. Arab astronomers
achieved for the most part much greater
precision; in the case of Ulugh Beg, the
error was only -0’32”.
His results for the calculation of the
movement of the planets are also
impressively close to those obtained by
modern means. Some consider his most
significant achievement to be the
compilation of a catalogue of the stars
and their locations. This was the first
such catalogue based on new, direct
observation since that complied some
1600 years earlier by the important
Greek astronomer Hipparchus. Our
appreciation for Ulugh Beg’s work
increases when we remember that he was
working nearly two centuries prior to the
invention of the telescope.

His work eventually became known in
Europe, with the publication in London
in 1650 of a Latin translation of his
“Chronology,” and fifteen years later the
first of many European editions of his
star tables. As Krisciunas points out, the
impact on European astronomy was slight
though, given the advances that had been
made prior to the time when Ulugh Beg’s
work became known. The Samarkand
observatory was much more important for
its influence on astronomy in Mughal
India. That said, Ulugh Beg
was certainly the most important
observational astronomer of the 15th
century. He was one of the first to
advocate and build permanently mounted
astronomical instruments. His catalogue of
1018 stars (some sources count 1022) was
the only such undertaking carried out
between the times of Cladius Ptolemy (ca.
170 A.D.) and Tycho Brahe (ca. 1600).
And…his attitude towards scientific

endeavors was surprisingly
modern.(Krisciunas)
References:
1) Aydin Sayili, The Observatory in Islam
and Its Place in the General History of the
Observatory (Ankara, 1960), Ch. VIII, pp.
260-289
2)Kevin Krisciunas, “Ulugh Beg’s Zij,” in
H. B. Paksoy, ed., Central Asian
Monuments (Istanbul, 1992). A
professional astronomer’s assessment, with
extensive bibliography
3) Iz istorii epokhi Ulugbeka (Tashkent,
1965)
4) Bernhard du Mont, “Ulugh Beg:
Astronom und Herrscher in Samarkand,”
Sterne und Weltraum, 2002, Nos. 9-10,
pp. 38-46. The first of two beautifully
illustrated articles on Ulugh Beg by
German astronomers; published in a
high-quality popular astronomy journal

5) Heiner Schwan, “Die Tabellen von
Ulugh Beg: Die Sternkataloge des
Ptolemäus, Ulugh Beg und Tycho Brahe
im Vergleich,” Sterne und Weltraum,
2002, Nos. 9-10, pp. 48-51.
https://depts.washington.edu/silkroad/citi
es/uz/samarkand/obser.html

================================
Mohammed Targai Ulugh Beg (1393 –
1449 C.E.)
By Dr. A. Zahoor
Ulugh Beg was a grandson of Timur
(known in the West as Tamerlane), a
Tartar prince and ruler of Turkestan. He
was an exceptional astronomer and
mathematician of the fifteenth century.
Ulugh Beg was the son of Timurid king
Shah Rukh and was born in 1393 at
Sultaniyya in Central Asia. He was a
Hafiz, someone who can recite the Qur’an
by heart.
Ulugh Beg made Samarkand famous as
one of the leading cities of Muslim
civilization. In 1424 he built a madrasa,
an institution of higher learning, where
astronomy was taught. Later in 1428,
Ulugh Beg began the construction of a
magnificent three-story observatory in
Samarkand. It was more than two

hundred fifty feet in diameter and one
hundred twenty feet high. He appointed
Ali-Kudsi, a Muslim astronomer as the
director of the Observatory. Several well-
known mathematicians and astronomers
including Al-Kashi and Kadizada
worked there.
He equipped it with the best and most
accurate astronomical instruments
available then. The observatory included
a Fakhri sextant (made of marble) which
was used for determining the inclination
of the ecliptic to the equator, the point of
the vernal equinox, the length of the
tropical year, and other astronomical
constants measured from observation of
the sun. It also included a quadrant so
large that part of the ground was removed
to allow it to fit in the Observatory. Other
instruments included a triquetram and
an armillary sphere.
In 1437 he published his most famous
and enduring work, a new catalogue of

stars entitled ‘Zidj-i Djadid Sultani.’ In
it, he revisited the positions and
magnitudes of stars observed by Ptolemy.
He found many errors in the
computations of Ptolemy. It includes a
diverse collection of observations and
computations, the position of the fixed
stars, the course of the stars, and the
knowledge of time. An English translation
of this work was published in 1917.
Ulugh Beg computed the length of the
year as 365 days 5 hours 49 minutes 15
seconds, a fairly accurate value. In
addition, he prepared Tables of Planetary
Motions which were very popular and in
demand throughout the astronomical
community. Ulugh Beg studied the yearly
movements of the five bright planets:
Saturn, Jupiter, Mars, Venus, and
Mercury. His data are still considered very
accurate. In 1437, he also compiled a star
catalogue giving the positions of 992 stars.
His compilation of tables of sines and

tangents at one-degree intervals are
accurate to eight decimal places.
Ulugh Beg was assassinated in 1449 in
Samarkand after a brief reign as ruler of
Turkestan for three years. This
catastrophe led to the neglect of the
observatory and Samarkand slowly
phased out as the leading center of
astronomy. The observatory was
eventually destroyed and its location was
confirmed in 1908 by Russian
archaeologists. Beer and Madler in their
famous work Der Mond (1837) mention a
surface feature of the moon after Ulugh
Beg. It is the name of a prominent
elliptical ring in the northwest of the
Eighteenth section.
http://www.unhas.ac.id/rhiza/arsip/saint
is/beg.html

Фрагмент двойного азимутального
квадранта
================================
The Tragic Story of the Man Who
Unlocked the Universe

By Jamie Carter
Nov 27, 2018
When it comes to places with an evocative
name, Samarkand in Uzbekistan, Central
Asia, on the old Silk Road is right up
there with Marrakesh, Timbuktu and
Shangri-La. It’s home to the UNESCO
World Heritage Site of the Registan, and
it’s where every single tourist who ever
visits Uzbekistan ends up. However, a few
miles away in a far less dramatic a
building is evidence that it was here that
astronomers accurately calculated the
length of a year to within a minute,
measured the Earth, and plotted the
positions of over a thousand stars.
The forgotten astronomer
Yet instead of taking his place next to the
giants of pioneering astronomy, such as
Tycho Brahe, Copernicus, Kepler, and
Galileo – all of whom he preceded – the

name Ulugh Begh remains virtually
unknown.
Where is Uzbekistan?
Most people cannot find Uzbekistan on a
world map. This former Soviet state is in
Central Asia, borders all of the other
‘Stans (Kazakhstan, Turkmenistan,
Tajikistan and Kyrgyzstan), and is home
to 33 million. Even fewer people,
including astronomers, have heard of
Begh.
Pioneering observations
The astronomical school he founded was
fleeting, but it was nonetheless pioneering.
Constructed around the year 1420 on a
hill on the outskirts of Samarkand, ruler
Begh’s cutting-edge observatory was
destroyed less than 30 years later. As was
Begh himself, murdered aged 55 years,
while on the way to Mecca – by an
assassin hired by his son! Archaeologists

only found the observatory in 1908, and
excavated it in 1948.
What’s left to see
The remains of his observatory are well
worth a visit if you want a glimpse of
what astronomy would have been like
without the telescope ever being invented.
It constitutes a huge trench along the line
of the Meridian, a few meters wide, that
once housed a mighty sextant with a
radius of 40 meters used to measure the
elevation of the Sun, Moon and stars. At
one end is an arch used to measure
midday. Starlight would have shone on to
the track, which contains Arabic
numerals. The result of this, and other
observational astronomical instruments
was the Zij-i Sultani in 1437, then the
most accurate catalog of 1,018 stars, and
Begh’s legacy.
Accurate calculations

In it, the astronomers accurately
predicted, for the first time, the exact
length of years and months, and the
moment of midday, and of winter and
summer solstices. The astronomers’
calculation of a year, at 365 days, 6
hours, 10 minutes and 8 seconds, was
later proved to be wrong. They were out by
1 minute and 2 seconds.
Predicting eclipses
The annual motion of the planets was
plotted, part of some impressive work
exploring the ecliptic. The ecliptic is the
sun’s apparent path through the sky
during a year. By measuring its
inclination to the celestial equator, Begh’s
astronomers calculated the Moon’s
ascending and descending nodes, and as a
result, the exact timing of solar eclipses
(which only occur when the moon crosses
the ecliptic).
Begh’s name lives on

This scholarly ruler’s name has largely
been forgotten by modern astronomy, but
it does live on in two places in the
Universe: 2439 Ulugbek, a minor planet
discovered in 1977, and Ulug Beigh
crater near the Oceanus Procellarum in
the northwest of the moon.
Uzbekistan’s only contribution to science?
Not quite. Muhammad ibn Musa al-
Khwarizmi, a 9th-century Muslim
mathematician and astronomer, invented
algebra. Go figure.
https://www.forbes.com/sites/jamiecartere
urope/2018/11/27/the-tragic-story-of-
the-man-who-unlocked-the-
universe/#b09310f4b0bd
==============================
Ulugh Beg‘s observatory, Uzbekistan
The site comprises the remains of a
meridian arc that originally formed part
of the 15th-century observatory of Ulugh
Beg. This colossal quadrant, its white

marble slabs containing incised Arabic
symbols and numerals, was constructing
by cutting its lower part out of living rock
while its upper part was supported by a
brick structure 40m high.
Ulugh Beg, the ruler of Transoxiana from
1409 to 1449, had been interested in
astronomy from childhood and had
visited the remains of Maragha
Observatory in his younger years. In 1420
he established a school in his capital city
Samarqand, where mathematical sciences
were taught, and after four years he
established his own observatory, one of
the largest in the pre-modern era.
The observatory was a large round
building with three stories, decorated
with glazed tiles, majolica and mosaic. Its
main instrument was a huge sextant with
a radius of 40m, embedded in a trench
about two metres wide, dug into a hill in
the plane of the meridian. This method of
construction made the instrument

completely stable and reduced the errors
arising from the minor displacements
common in movable observational tools.
At the same time, the enormous size of the
sextant made its graduation very accurate.
On the arc of the sextant, divisions of
70.2 cm represented one degree, while
marks separated by 11.7 mm
corresponded to one minute and marks
only 1mm apart represented five seconds.
Following the demise of Ulugh Beg the
observatory was reduced to ruins. Its
remains, primarily the sextant, were
discovered in 1908.
The main purpose of the observatory was
to produce a zīj, and the Sultānī Zīj or
the Zīj-i Ulugh Beg was duly compiled in
1438-39. This became one of the most
widespread zījs: it was copied more than
a hundred times, translated into Arabic
and Turkish, and parts of it were
translated into Latin and published in

Oxford and London in the mid 17th
century.
An important aspect of the Sultānī Zīj is
its updated values for astronomical
parameters and new computational
procedures. Samarqand astronomers
attempted to calculate the trigonometric
tables from scratch and derived new
values for essential parameters. The basis
of the trigonometric tables of the Sultānī
Zīj is the very accurate calculation of the
sine of 1°, which Ulugh Beg Ghiyāth al-
Dīn Jamshid al-Kāshī, the senior
astronomer of the observatory, calculated
using new procedures to sixteen decimal
places. His work the Key to Arithmetic is
one of the best treatises written about
arithmetic in the Middle Ages.
Under the patronage of Ulugh Beg,
Samarqand became an ideal place to
study science at an advanced level, and
attracted many students from all over the
Islamic territories, even including the

farthest western regions. As a result of
these scholarly exchanges, the influence
of Samarqand Observatory, which was
itself a continuation of the Maragha
School tradition, spread through a vast
area from Tranoxiana to the Ottoman
Empire. The social and political
turbulence that followed the fall of Ulugh
Beg and continued until the
establishment of the Safavid dynasty in
Persia in the early 1500s triggered a
massive emigration of scholars from the
eastern parts of the Islamic territories into
the Ottoman Empire. Among them were
several astronomers and mathematicians
who were either working at the
Samarqand Observatory or else trained by
Samarqand scholars; and their influence
upon the development of science in the
Ottoman Empire was considerable.
Ulugh Beg’s observatory forms part of the
World Heritage Site Samarkand—
Crossroads of Cultures, inscribed in 2001

under criteria (i), (ii) and (iv). As one of
the major monuments of the property, it is
afforded Uzbekistan’s highest level of
cultural protection and conservation.
https://www3.astronomicalheritage.net/in
dex.php/show-entity?idunescowhc=603
==============================
The Samarkand Observatory
A comment from Clive J. Grant reads:
The Samarkand observatory, for the
construction of which Ulugh Beg was
primarily responsible, was left untouched
when Samarkand was conquered by
Uzbeks in 1500. Samarkans was
incorporated into the Bukhara Khanate.
This is very important, because the city of
Bukhara, even then, was becoming a
major repository of Islamic written (and,
later, printed) works. It grew into a major
trading center and thousands of precious
scrolls and books traveled the Silk Road
to western centers of Islamic learning. In

large measure, that is why we have
available to us the works of so many
11th- to 15th-century Islamic scholars.
Samarkand declined in importance until,
for about 50 years (172[?] to 177[?]) it
had no inhabitants. Long before then,
virtually every scrap of paper, silk scroll,
papyrus, vellum, &c. had been removed to
the covered souks in Bukhara. Imperial
Russia partially resurrected Samarkand
as a rail center during the 19th-Century
Great Game.
Over the centuries, the Bukhara souks
had developed into the single largest
documentary resource in all of Islam. In
some respects, it was a marketing center;
in some it was a giant library. Sadly, that
first-place distinction was annihilated
early in the 20th-Century.
In their first attempt to force Bukhara
into the new Red USSR empire, the
Bolsheviks were repelled by a small
patriotic force. As punishment, Moscow

named Samarkand the capital of the
Uzbek Soviet Socialist Republic and,
simultaneously, sent a modern army
against the ancient city. The
overwhelming force included heavy
artillery, tanks and heavy bombing raids
by airplanes. Nothing of the Bukhara
archives survived. The canvas covered
souks were as ineffective as air against
explosives and incendiary devices.
Of course, history tends to be written by
the conquerors and the USSR, with a
penchant for revising history at the drop
of a hat, tried to write the barbaric
destruction of Bukhara out of history.
Western left wing authors occasionally
make reference to the ruins of ancient
covered bazaars, unwilling as they are to
lay the blame where it belongs.
Here are quotations from some paragraphs
in David Fromkin’s book, A Peace to End
All Peace , chapter 56, A Death in
Bukhara [of 1918] p. 485

… In the city’s seven-mile honeycomb of
covered bazaars, … [t]here was a lively
traffic … A center of the commerce in rare
manuscripts and libraries in many
oriental languages, Bukhara continued to
be the principal book market in Central
Asia.
[of 1920] p. 486
In the summer of 1920 the Red Army
attacked again, and Russian troops under
the command of Mikhail Frunze
bombarded Bukhara. . . . the Red Army,
with its airplanes and armored vehicles,
moved forward on 2 September, bringing
Bukhara’s medieval rule to an end: the
library, containing possibly the greatest
collections of Moslem manuscripts in the
world, went up in flames.
One can only speculate what untold
treasures went up in smoke.
and.ac.uk/Extras/Samarkand.html

Ουλούγ Μπεκ: ο Αστρονόμος Σουλτάνος του Τουρκεστάν, ο πιο Πολυμαθής Αυτοκράτορας των Τελευταίων 2500 Ετών, Εγγονός του Ταμερλάνου

Ουλούγ Μπεκ: ο Αστρονόμος Σουλτάνος του Τουρκεστάν, ο πιο Πολυμαθής Αυτοκράτορας των Τελευταίων 2500 Ετών, Εγγονός του Ταμερλάνου

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Ουλούγ Μπεκ: ο Αστρονόμος Σουλτάνος του Τουρκεστάν, ο πιο Πολυμαθής Αυτοκράτορας των Τελευταίων 2500 Ετών, Εγγονός του Ταμερλάνου