Non-contact probe measurement test bed for millimeter wave and terahertz circuits, integrated devices/components, systems for spectroscopy using sub-wavelength-size-samples

US 9,488,572 B2
Filed: 06/19/2014
Issued: 11/08/2016
Est. Priority Date: 06/19/2013
Status: Active Grant

First Claim

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1. An apparatus for performing terahertz (THz) or millimeter wave (mmW) characterization of an associated device-under-test (DUT), the apparatus comprising:

a test fixture configured to hold the associated DUT, the test fixture including first and second off-axis planar antennas designed to transmit and receive along different respective first and second off-axis directions, and a planar waveguide arranged to guide THz or mmW radiation between the first and second off-axis planar antennas and further configured to couple THz or mmW radiation guided between the first and second off-axis planar antennas with the associated DUT held by the test fixture, wherein the test fixture includes no wired connection to a THz or mmW signal source;

a beam forming apparatus arranged to wirelessly transmit a probe THz or mmW beam along the first off-axis direction to the first off-axis planar antenna of the test fixture; and

a THz or mmW receiver arranged to wirelessly receive a THz or mmW signal emitted along the second off-axis direction by the second off-axis planar antenna responsive to transmission of the probe THz or mmW beam to the first off-axis planar antenna.

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Abstract

A test fixture for characterizing a device-under-test (DUT) includes first and second planar antennas and a planar waveguide arranged to guide terahertz (THz) and/or millimeter wave (mmW) radiation between the first and second planar antennas. The planar waveguide is further configured to couple THz and/or mmW radiation guided between the first and second planar antennas with the DUT. A beam forming apparatus is arranged to transmit a probe THz and/or mmW radiation beam to the first planar antenna of the test fixture. An electronic analyzer is configured to wirelessly receive a THz and/or mmW signal emitted by the second planar antenna responsive to transmission of the probe THz and/or mmW radiation beam to the first planar antenna. The planar antennas may be asymmetrical beam-tilted slot antennas.

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27 Claims

1. An apparatus for performing terahertz (THz) or millimeter wave (mmW) characterization of an associated device-under-test (DUT), the apparatus comprising:
- a test fixture configured to hold the associated DUT, the test fixture including first and second off-axis planar antennas designed to transmit and receive along different respective first and second off-axis directions, and a planar waveguide arranged to guide THz or mmW radiation between the first and second off-axis planar antennas and further configured to couple THz or mmW radiation guided between the first and second off-axis planar antennas with the associated DUT held by the test fixture, wherein the test fixture includes no wired connection to a THz or mmW signal source;
  
  a beam forming apparatus arranged to wirelessly transmit a probe THz or mmW beam along the first off-axis direction to the first off-axis planar antenna of the test fixture; and
  
  a THz or mmW receiver arranged to wirelessly receive a THz or mmW signal emitted along the second off-axis direction by the second off-axis planar antenna responsive to transmission of the probe THz or mmW beam to the first off-axis planar antenna.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15)
- - 2. The apparatus of claim 1 further comprising:
    - a vector network analyzer (VNA) operatively coupled with the THz or mmW receiver.
  - 3. The apparatus of claim 1 further comprising:
    - an electronic analyzer operatively coupled with the THz or mmW receiver and configured to perform spectroscopic analysis of the wirelessly received THz or mmW signal.
  - 4. The apparatus of claim 1 wherein the first and second off-axis planar antennas are first and second asymmetrical beam-tilted slot antennas.
  - 5. The apparatus of claim 4 wherein the first and second off-axis planar antennas are first and second asymmetrical beam-tilted double slot antennas.
  - 6. The apparatus of claim 1 wherein the beam forming apparatus includes:
    - a THz or mmW radiator; and
      
      a lens focusing THz or mmW radiation from the THz or mmW radiator onto the first off-axis planar antenna of the test fixture to form the probe THz or mmW beam.
  - 7. The apparatus of claim 6 further comprising:
    - a receiving lens conveying the THz or mmW signal emitted by the second off-axis planar antenna to the THz or mmW receiver.
  - 8. The apparatus of claim 7 wherein the THz or mmW radiator comprises a horn antenna and the THz or mmW receiver comprises a horn antenna.
  - 9. The apparatus of claim 8 wherein the THz or mmW radiator further comprises an off-axis parabolic mirror and the THz or mmW receiver further comprises an off-axis parabolic mirror.
  - 10. The apparatus of claim 7 comprising:
    - a unitary lens defining the lens focusing THz or mmW radiation from the THz or mmW radiator onto the first off-axis planar antenna and defining the receiving lens conveying the THz or mmW signal emitted by the second off-axis planar antenna to the THz or mmW receiver.
  - 11. The apparatus of claim 10 wherein the unitary lens includes:
    - a hemispherical side defining the lens focusing THz or mmW radiation from the THz or mmW radiator onto the first off-axis planar antenna and defining the receiving lens conveying the THz or mmW signal emitted by the second off-axis planar antenna to the THz or mmW receiver; and
      
      a planar back side on which the test fixture is disposed.
  - 12. The apparatus of claim 10 wherein:
    - the test fixture further includes a substrate wafer or chip on which the first and second off-axis planar antennas and the planar waveguide are fabricated;
      
      the unitary lens includes a lensing side and a planar second side; and
      
      the substrate wafer or chip of the test fixture is disposed on the planar second side of the unitary lens.
  - 13. The apparatus of claim 1 further comprising:
    - DC probes configured to contact the associated DUT to apply a DC bias to the associated DUT.
  - 14. The apparatus of claim 1 wherein the test fixture further includes:
    - a substrate wafer or chip on which the first and second off-axis planar antennas and the planar waveguide are fabricated.
  - 15. The apparatus of claim 1 wherein the test fixture comprises an integrated circuit including a substrate wafer or chip on which are fabricated the first and second off-axis planar antennas, the planar waveguide, and the associated DUT.

16. An apparatus for performing characterization of an associated device-under-test (DUT) fabricated as a component of a test fixture that further includes first and second beam-tilted planar antennas designed to transmit and receive along different respective first and second off-axis directions and a planar waveguide connecting the first and second beam-tilted planar antennas with the DUT, the apparatus comprising:
- a beam forming apparatus configured to wirelessly transmit a probe terahertz (THz) or millimeter wave (mmW) radiation beam to the first beam-tilted planar antenna of the integrated circuit along the first off-axis direction;
  
  a signal receiver configured to wirelessly receive a THz or mmW signal emitted by the second beam-tilted planar antenna along the second off-axis direction in response to receipt of the probe THz or mmW radiation beam at the first beam-tilted planar antenna along the first off-axis direction; and
  
  an electronic analyzer in wired connection with the signal receiver and configured to perform at least one of vector network analysis and spectroscopic analysis of the THz or mmW signal wirelessly received by the signal receiver.
- View Dependent Claims (17, 18, 19, 20, 21)
- - 17. The apparatus of claim 16 wherein the electronic analyzer is configured to perform vector network analysis of the THz or mmW signal wirelessly received by the signal receiver.
  - 18. The apparatus of claim 16 wherein the electronic analyzer is configured to perform spectroscopic analysis of the THz or mmW signal wirelessly received by the signal receiver.
  - 19. The apparatus of claim 16 wherein the beam forming apparatus includes:
    - a radiator configured to emit THz or mmW radiation; and
      
      a lens focusing THz or mmW radiation emitted by the radiator onto the first beam-tilted planar antenna of the test fixture along the first off-axis direction.
  - 20. The apparatus of claim 16 comprising:
    - a unitary lens configured to focus the probe THz or mmW radiation beam onto the first beam-tilted planar antenna along the first off-axis direction and to wirelessly couple the THz or mmW signal emitted by the second beam-tilted planar antenna along the second off-axis direction to the signal receiver.
  - 21. The apparatus of claim 16 further comprising:
    - DC probes configured to contact the associated DUT to apply a DC bias to the associated DUT.

22. An apparatus comprising:
- an integrated circuit including;
  
  a terahertz (THz) or millimeter wave (mmW) device under test (DUT),first and second planar antennas, anda planar waveguide arranged to guide THz or mmW radiation between the first and second planar antennas and further configured to couple THz or mmW radiation guided between the first and second planar antennas with the THz or mmW DUT by the planar waveguide having a first end connected with the first planar antenna, a second end connected with the second planar antenna, and the DUT connected with the planar waveguide between the first and second ends of the planar waveguide.
- View Dependent Claims (23, 24)
- - 23. The apparatus of claim 22 further comprising:
    - an electronic analyzer wirelessly connected with the THz or mmW DUT by wireless contacts comprising the first and second planar antennas.
  - 24. The apparatus of claim 23 further comprising:
    - DC probes configured to apply a DC bias to the THz or mmW DUT.

25. A method for characterizing a device-under-test (DUT), the method comprising:
- providing a test fixture including first and second planar antennas connected via the DUT;
  
  providing a short circuit fixture comprising the test fixture with the DUT replaced by a short circuit;
  
  providing a standard load fixture comprising the test fixture with the DUT replaced by a standard load;
  
  wirelessly transmitting probe THz or mmW radiation to the first planar antenna of the short circuit fixture and wirelessly receiving a short circuit signal emitted by the second planar antenna of the short circuit fixture responsive to the transmitting;
  
  wirelessly transmitting probe THz or mmW radiation to the first planar antenna of the standard load fixture and wirelessly receiving a standard load signal emitted by the second planar antenna of the standard load fixture responsive to the transmitting;
  
  wirelessly transmitting probe terahertz (THz) or millimeter wave (mmW) radiation to the first planar antenna of the test fixture;
  
  wirelessly receiving a THz or mmW signal characterizing the DUT which is emitted by the second planar antenna of the test fixture responsive to the transmitting;
  
  adjusting the THz or mmW signal characterizing the DUT based on the short circuit signal and the standard load signal to generate a calibrated THz or mmW signal characterizing the DUT; and
  
  analyzing the calibrated THz or mmW signal characterizing the DUT using a vector network analyzer (VNA).
- View Dependent Claims (26, 27)
- - 26. The method of claim 25 further comprising:
    - performing spectroscopic analysis on the received THz or mmW signal.
  - 27. The method of claim 25 wherein the providing comprises:
    - monolithically fabricating on a substrate wafer or chip the DUT, the first and second planar antennas, and a waveguide connecting the first planar antenna and the second planar antenna with the DUT.

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Current Assignee
Ohio State Innovation Foundation (Ohio State University)
Original Assignee
Ohio State Innovation Foundation (Ohio State University)
Inventors
Sertel, Kubilay, Caglayan, Cosan, Trichopoulos, Georgios
Primary Examiner(s)
Porta, David
Assistant Examiner(s)
Maupin, Hugh H

Application Number

US14/309,432
Publication Number

US 20150102225A1
Time in Patent Office

873 Days
Field of Search
US Class Current

1/1
CPC Class Codes

G01N 21/3581 using far infrared light; u...

G01R 31/2822 of microwave or radiofreque...

Non-contact probe measurement test bed for millimeter wave and terahertz circuits, integrated devices/components, systems for spectroscopy using sub-wavelength-size-samples

First Claim

2 Assignments

0 Petitions

Accused Products

Abstract

11 Citations

27 Claims

Specification

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Non-contact probe measurement test bed for millimeter wave and terahertz circuits, integrated devices/components, systems for spectroscopy using sub-wavelength-size-samples

First Claim

2 Assignments

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0 Petitions

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Accused Products

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Abstract

11 Citations

27 Claims

Specification

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Solutions

Use Cases

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