status of kvn instrumental phase calibration system development
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Status of KVN Instrumental Phase Calibration System Development. - PowerPoint PPT PresentationTRANSCRIPT
Status of KVN Instrumental Phase Calibration System Development
Do-Heung Je1, Moon-Hee Chung1, Ji-Man Kang1, Seung-Rae Kim1, Min-Kyu Song1, Sung-Mo Lee1, Taehyun Jung1, Seog-Tae Han1, Do-Young
Byun1, Seog-Oh Wi1, Bong-Won Son1, Soo-Yeon Kim2, and Won-Kyu Lee3
1Korea Astronomy and Space Science Institute2Korea University
3Korea Research Institute of Standards and Science
2013. Oct. 12.2nd IVTW
Contents• KVN Round Trip System
– Specification– Development progress– System configuration– Test results (old & new)
• KVN Wide-band phase calibration– Specification : power vs freq, reference frequency – P-cal System Configuration – Component’s design and fabrication– Timeline
KVN System Configuration
H-maser
Antenna Receiver Room
43 GHz FE
22 GHz FE
1 pps Distributor
100 MHz Distributor
10 MHz Distributor
1 pps Distributor
5 MHz
1.4 GHz
Control Room
WDMOptical
MUX
Digi-talE/O
Down Con-
verter
Down Con-
verter
Sampler
Sampler
WDMOpticalDMUX
Digital O/E
DigitalFilters
Mk5B
IF Selector
StationClock
1 pps
ReferenceGenerator
RTS Antenna Module
RTS Control Room Module
1.4 GHz
10 MHz100 MHz
Down Con-
verter
Down Con-
verter
Sampler
Sampler
86 GHz FE
129 GHz FE
QO
x2
P-cal(under de-velopment)
RTS (3 sets installed in 2012)
KVN RTS(Round Trip System) Speci-fication
• RTS is needed for compensating the cable length change due to temperature variations & move-ment
• H-maser frequency stability : ~ 2E-15@1000s• RTS transmission stability : ~ 2E-16@1000s (10
times better than H-maser stability)
KVN RTS Development• KASI developed KVN RTS through research coop-
eration with KRISS (Korea Research Institute of Standards and Science) in 2011.
• KASI installed RTS system in 3 KVN sites in 2012. • Fiber-optic reference signal transmission method
(from NICT, Dr. Fujieda, 2009)• The measured stability satisfied the stability spec-
ification, 2E-16@1,000s.• Real-time remote signal monitoring function
was added.
KVN RTS Configuration ,
,,
.
Remote signal phase cannot be measured directly. We need any method to check remote signal phase for diagnosis of the system performance.
Expectation of remote signal phase
𝜑𝑣𝑐𝑜+𝜑 𝑓𝑖𝑏𝑒𝑟=𝜑𝑟𝑒𝑚𝑜𝑡𝑒
.
() ,
.
𝜑𝑣𝑐𝑜=𝜑𝑟𝑒𝑚𝑜𝑡𝑒−𝜑 𝑓𝑖𝑏𝑒𝑟
Remote signal phase can be expected from vco signal phase and round-trip signal phase.
laser
VCO
MZM
Photo Diode
H-maser
𝑉 𝑣𝑐𝑜
Phase Compensation Circuit
𝑉 𝑟𝑡
𝑉 𝑟𝑒𝑓
𝑉 𝑐
Observation Building
Antenna Vertex Room
laser MZM
Photo Diode𝑉 𝑟𝑒𝑚𝑜𝑡𝑒
Vector Voltmeter
𝑉 𝑟𝑒𝑓
𝑉 𝑣𝑐𝑜
𝑉 𝑟𝑡
Controller
KVN RTS Test setup
Test results I (2011. June)
Test results II (2012. Jan.)
Test results III (after temperature stabilization)
Test results IV (after temperature stabilization)
Comparison of Allan deviations before and after temperature stabilization
After stabiliza-tion
Before stabi-lization
Contents• Round Trip System
– Specification– Development progress– System configuration– Test results (old & new)
• Wide-band phase calibration– Specification : power vs freq, reference frequency – System Configuration – Component’s design and fabrication– Timeline
KVN 4 ch Receiver (Front End)
45 degree mirror
KVN Wide-band Pcal Specification• Quasi-optic injection is needed for calibrate path
delays in 4 bands receivers• Frequency band : 20 – 130 GHz
– Covers KVN 4 ch receiver full bandwidth• Reference frequency : 200 MHz
– 2 tone signals are positioned in 500 MHz IF bw• Power : ~ - 100 dBm (in front of each receiver’s
horn antenna)
KVN P-cal ConfigurationRefer-ence
Genera-tor
Feeder
Comb Genera-
tor
100 MHz
200 MHz
20-130 GHzAttenua-
torQuasi-Optic
Injection
Double-ridged feed-horn
doubler Power Amp
< 50 GHz
Quasi Optic Injection• KVN is comprised of 3 LPF, several mirrors. • Quasi optic P-cal injection is needed.• Double ridged feedhorn, ellipsoidal mirror, Mylar
sheet are used for quasi optic P-cal injection.
To subreflec-tor
Ellip-soidal mirror
MylarFilm
45 degree mirror
Double-ridged horn
Mylar Film Transmission Loss
125 um50 um25 um
Comb Generator• Signal Generation
– Step Recovery Diode: ~ 20 GHz– Tunnel Diode : ~ 40 GHz– NLTL (Nonlinear Transmission Line) Comb generator : > 100 GHz
• PSPL : -30 dBm @ 50 GHz (200 MHz reference)• Agilent : -85 dBm@ 67 GHz (10 MHz reference)
Wideband Feed Horn Development (Dr. Moon-Hee Chung)
• Double-ridged waveguide horn was designed and fabricated as a ul-tra-wide band feeder
• VSWR : < 2 @ 20-130 GHz • Aperture size : 24 mm x 28 mm• Lower return loss measured above 80 GHz
Timeline for KVN wideband P-cal• P-cal system using commercial comb generator(<
50 GHz or 86 GHz), wideband feeder, Quasi-optic injection system– 1st injection test : 2013. Dec.– 2nd injection test : 2013. March.– 3 sets installation : 2014. July (TBD)
• Further Works for full-band Phase calibration – NLTL MMIC Chip development needed.– MMIC Module loaded feeder development.
Summary• KVN RTS development
– 2E-16 @ 1000s – O(E-17) @ 1000s (after temperature stabilization) – Real time remote signal phase expectation method
was suggested.• KVN wide-band Pcal system is under develop-
ment – Ultra wide-band feed is developed. – Quasi-optic injection – Custom designed high frequency comb generator is
needed.