Agilent Technologies 8510 manual Offset loss, GHz C Z, Log e10, 1GHz

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Z0 =

1

 

 

In(

D

) = 59.9585

r

In(

D

)

2π

 

ε

d

εr

d

r = relative permeability constant of the medium (equal to 1.0 in air)

εr = relative permittivity constant of the medium (equal to 1.000649 in air)

D = inside diameter of outer conductor d = outside diameter of inner conductor

The 8510 requires that the characteristic imped- ance of waveguide transmission line is assigned to be equal to the SET Z0.

The characteristic impedance of other transmis- sion media is not as easily determined through mechanical dimensions. Waveguide impedance, for example, varies as a function of frequency. In such cases, normalized impedance measurements are typically made. When calibrating in waveguide, the impedance of a “matched” load is used as the impedance reference. The impedance of this load is matched that of the waveguide across frequency. Normalized impedance is achieved by entering SET Z0 and OFFSET Z0 to 1 ohm for each standard.

Offset Z0 equal to system Z0 (SET Z0) is the assigned convention in the 8510 for matched wave- guide impedance.

Offset loss

Offset loss is used to model the magnitude loss due to skin effect of offset coaxial type standards only. The value of loss is entered into the standard defi- nition table as gigohms/second or ohms/nanosec- ond at 1 GHz.

The offset loss in gigohms/second can be calculat- ed from the measured loss at 1 GHz and the physi- cal length of the particular standard by the following equation.

Offset loss (

 

G

)

 

 

=

dBloss

1 GHz C Z0

 

 

 

 

 

 

s

 

1 GHz

10 loge(10)

r

 

 

 

 

 

where:

dBlOSS 1 GHz =measured insertion loss at 1 GHz Z0 = offset Z0

= physical length of the offset

The 8510 calculates the skin loss as a function of frequency as follows:

Offset loss

 

 

G

 

= Offset loss

 

 

G

 

 

f(GHz)

(

s )

(

s )

1GHz X

 

 

 

Note: For additional information refer to Appendix C.

For all offset standards, including shorts or opens, enter the one way skin loss. The offset loss in waveguide should always be assigned zero ohms by the 8510.

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Contents Dis Product Information For Support Reference Only Table of contents Measurement calibration Measurement errorsIntroduction Calibration kit Standard definition Class assignmentStandard definitions table Standard class assignments Modification procedure Select standardsDefine standards Standard definition modelsOpen circuit capacitance C0 , C1 , C2 and C3 Standard numberStandard type ΠfX ΠfZ∆∅radians = 2πf ∆length Short circuit inductance L0 , L1, L2 and L3Terminal impedance Offset delayFixed or sliding Linear delay Actual delay = Fco/f2 Offset Z0Log e10 Offset lossGHz C Z 1GHzLower/minimum frequency Coax or waveguide ∅radians = 2π = 2πfdelayUpper/maximum frequency Λg = λ Co2Standard Classes Assign classesStandard labels Reverse transmission match and thru S11 A,B,C and S22 A,B,CForward transmission match and thru IsolationTRL Line TRL ThruTRL Reflect TRM ThruCalibration kit label Standard Class labelsTRL options Enter standards/classes Verify performanceModeling a thru adapter User modified cal kits and Agilent 8510 specificationsModification examples Modeling an arbitrary impedance standardTo load calibration kits from disk into Agilent Appendix a Calibration kit entry procedureDisk procedure To store calibration kits from the Agilent 8510 onto a diskFront panel procedure P-band waveguide example Pshort Type-N coaxial connector interface Appendix B Dimensional considerations in coaxial connectorsMm coaxial connector interface Female type-N Page Appendix C Cal coefficients model EquationTheir first order approximations, R is small and G=0, are Then Agilent Open Agilent Email UpdatesAgilent Direct