technologies for mm and sub-mm waves sideband separating … · 2016-06-10 · view south from...

View south from Cerro Chajnantor. Photo S. Radford 1994 November

Technologies for mm and sub-mm waves

sideband separating receivers

Victor Belitsky

Group for Advanced Receiver Development (GARD)

Earth and Space Science Department

Chalmers University of Technology

Gothenburg

• 2SB SIS mixer receivers - introduction;

• SIS mixer improvements;

• Passive components of the 2SB mixer;

• LO sources;

• SEPIA.

Outline

Victor Belitsky, GARD, Chalmers University

2SB Mixers - intro

Victor Belitsky, GARD, Chalmers University

90° RF hybrid

V/√2

jV/√2

90° IF hybrid

LO

LSB

USB

Terminated

RF ½LSB ½USB

Mixer 2

Mixer 1

½LSB ½USB

½LSB ½LSB ½USB ½USB

½LSB ½USB ½USB ½LSB

• Symmetry in amplitude and phase;

• RF hybrid, DSB mixers, IF hybrid;

ALMA Band 5 is used as “show-case”

2SB Mixers – ALMA Band 5

Victor Belitsky, GARD, Chalmers University

90° RF hybrid

V/√2

jV/√2

90° IF hybrid

LO

LSB

USB

Terminated

RF ½LSB ½USB

Mixer 2

Mixer 1

½LSB ½USB

½LSB ½LSB ½USB ½USB

½LSB ½USB ½USB ½LSB

• Symmetry in amplitude and phase;

• RF hybrid, DSB mixers, IF hybrid;

ALMA Band 5 is used as “show-case”

2SB Mixers - intro

Victor Belitsky, GARD, Chalmers University

• Symmetry in amplitude and phase;

• RF hybrid, DSB mixers, IF hybrid;

2SB Mixers - intro

Victor Belitsky, GARD, Chalmers University

• Symmetry in amplitude and phase;

• RF hybrid, DSB mixers, IF hybrid;

SIS DSB Mixers

Victor Belitsky, GARD, Chalmers University

SIS DSB Mixers

Victor Belitsky, GARD, Chalmers University

SIS DSB Mixers

Victor Belitsky, GARD, Chalmers University

15 um substrate offset gives 12.5 degree in phase;

SIS DSB Mixers - improvement

Victor Belitsky, GARD, Chalmers University

15 um substrate offset gives 12.5 degree in phase;

90° RF hybrid

V/√2

jV/√2

90° IF hybrid

LO

LSB

USB

Terminated

RF ½LSB ½USB

Mixer 2

Mixer 1

½LSB ½USB

½LSB ½LSB ½USB ½USB

½LSB ½USB ½USB ½LSB

SIS DSB Mixers - improvement

Victor Belitsky, GARD, Chalmers University

SIS DSB Mixers - improvement

Victor Belitsky, GARD, Chalmers University

RF hybrid - improvement

Victor Belitsky, GARD, Chalmers University

90° RF hybrid

V/√2

jV/√2

90° IF hybrid

LO

LSB

USB

Terminated

RF ½LSB ½USB

Mixer 2

Mixer 1

½LSB ½USB

½LSB ½LSB ½USB ½USB

½LSB ½USB ½USB ½LSB

RF hybrid - improvement

Victor Belitsky, GARD, Chalmers University

RF hybrid - improvement

Victor Belitsky, GARD, Chalmers University

IF hybrid - improvement

Victor Belitsky, GARD, Chalmers University

Local Oscillator – SIS multiplier

Victor Belitsky, GARD, Chalmers University

Local Oscillator – SIS multiplier

Victor Belitsky, GARD, Chalmers University

Pumped SIS

mixer

Victor Belitsky, GARD, Chalmers University

Swedish ESO PI instrument for APEX

SEPIA February 2015: installed at APEX with ALMA Band 5

preproduction receiver.

February 2016: ALMA Band 9 (NOVA, NL) technically

commissioned after integration into SEPIA. Collaborative

effort by APEX partners: ESO and GARD/OSO; details in

the MoU.

Planned in 2017: 2SB version of ALMA Band 9 from NOVA;

Planned for 2018: GARD designed and built APEX B2

cartridge (=ALMA B7) receiver with IF 4-12 GHz;

Future upgrade of ALMA B5 to IF 4-12 GHz;

SEPIA Cryostat

Victor Belitsky, GARD, Chalmers University

SEPIA Cryostat

Victor Belitsky, GARD, Chalmers University

SEPIA Receiver

Victor Belitsky, GARD, Chalmers University

SEPIA First Light Receiver

Billade, B., Nystrom, O. ; Meledin, D. ; Sundin, E. ; Lapkin, I. ; Fredrixon, M. ; Desmaris, V. ; Rashid, H. ;

Strandberg, M. ; Ferm, S.-E. ; Pavolotsky, A. ; Belitsky, V., "Performance of the First ALMA Band 5 Production

Cartridge", IEEE Trans. Terahertz Science and Technology, Vol. 2, No. 2, March 2012, pp. 208-214.

165 170 175 180 185 190 195 200 2050

50

100

150

200

LO Frequency (GHz)

Nois

e T

em

pera

ture

(K),

PO

L-0

Un-corrected Average Noise Temperature measured over, IF = 4 GHz - 8 GHzEach point represents noise averaged over 4-8 GHz IF, at corresponding LO

CH1(LSB)

CH2(USB)

ALMA Specification 80% - 55K

ALMA Specification @ any frequency - 75K

165 170 175 180 185 190 195 200 2050

50

100

150

200

LO Frequency (GHz)

Nois

e T

em

pera

ture

(K),

PO

L-0

True (Corrected for sideband rejection) Average Noise Temperature measured over, IF = 4 GHz - 8 GHzEach point represents noise averaged over 4-8 GHz IF, at corresponding LO

CH1(LSB)

CH(USB)

ALMA Specification 80% - 55K

ALMA Specification @ any frequency - 75K

165 170 175 180 185 190 195 200 2050

50

100

150

200

LO Frequency (GHz)N

ois

e T

em

pera

ture

(K),

PO

L-1

Un-corrected Average Noise Temperature measured over, IF = 4 GHz - 8 GHzEach point represents noise averaged over 4-8 GHz IF, at corresponding LO

CH1(LSB)

CH2(USB)

ALMA Specification 80% - 55K

ALMA Specification @ any frequency - 75K

165 170 175 180 185 190 195 200 2050

50

100

150

200

LO Frequency (GHz)

Nois

e T

em

pera

ture

(K),

PO

L-1

True (Corrected for sideband rejection) Average Noise Temperature measured over, IF = 4 GHz - 8 GHzEach point represents noise averaged over 4-8 GHz IF, at corresponding LO

CH1(LSB)

CH(USB)

ALMA Specification 80% - 55K

ALMA Specification @ any frequency - 75K

SEPIA First Light Receiver

Billade, B., Nystrom, O. ; Meledin, D. ; Sundin, E. ; Lapkin, I. ; Fredrixon, M. ; Desmaris, V. ; Rashid, H. ;

Strandberg, M. ; Ferm, S.-E. ; Pavolotsky, A. ; Belitsky, V., "Performance of the First ALMA Band 5 Production

Cartridge", IEEE Trans. Terahertz Science and Technology, Vol. 2, No. 2, March 2012, pp. 208-214.

SEPIA: Flexible and Scalable

Receiver Platform

Acknowledgements GARD/OSO/Chalmers University

Rashid, H., Billade, B., Nystrom, O. ; Meledin, D. ; Sundin, E. ; Lapkin, I. ; Fredrixon,

M.; Desmaris, V. ;; Strandberg, M. ; Ferm, S.-E. ; Pavolotsky, A. ; Olberg M.; Aghdam P.;

Ermakov A.; de Beck E.; Bergman P.; Olofsson H.; Shafiee S.; Conway J.

ESO

De Breuck C.; Immer K.; Yagoubov P.

APEX

Big thanks to everybody of the Engineering staff and Astronomers for support and

help! Special thanks to Thomas Klein as well !