|
Configurations |
Type |
Min Freq. (MHz) |
Max Freq. (MHz) |
Characteristics |
Configuration Differences & Additional Details |
|
A, B |
DC isolated primary and secondary with center tap |
0.01 |
1400 |
• Exhibits very high DC isolation. • Center tap enables perfect grounding on both sides and provides better unbalance. |
Config A and Config B are very similar, except B has center tap available on the both sides. |
|
C, E, E1 |
DC isolated primary and secondary |
0.01 |
800 |
• No center tap. • Unbalance is affected due to virtual ground. |
• Config C provides DC isolation. • Config E and E1 are used for balun operation as primary connected to ground. • Config E1 is implemented using LTCC technology and can operate from 12 to 18 GHz. |
|
D, D1 |
Autotransformer |
0.05 |
2500 |
• Used for impedance transformation. • Allows for any impedance ratio based on number of turns. |
• Config D1 is modified version of config D. • Additional capacitor decouples the signal from ground and allows DC to pass. |
|
F |
Tri-filar |
0.01 |
200 |
• User customizable configuration. |
• This configuration consists of 3 lines all coupled to each other and can function differently depending on how the 3 lines are interconnected. |
|
G, K |
Transmission line transformer |
4.5 |
9000 |
• Available as core & wire or LTCC. • At lower frequency, coupling between lines is achieved through the magnetic core. • At higher frequency, the coupling is achieved through capacitive coupling. • The LTCC transmission lines are achieved through coupled transmission lines, and are limited in performance at lower frequencies. • Both configurations allow DC passing between primary and secondary windings. |
• Config G is a simple transmission line transformer, i.e. a bi-filar transformer. • Config K has an additional feedback winding which allows for DC current to be sourced to the Secondary ports without saturating the core, but requires external capacitors are for DC current to be sourced. |
|
Configurations |
Type |
Min Freq. (MHz) |
Max Freq. (MHz) |
Characteristics |
Configuration Differences & Additional Details |
|
H |
Guanella Transformer |
10 |
4500 |
• 4 winding transmission line transformer. • Typically provides 1:4 impedance ratio. • Commonly used as a balun. • Allows for current to be sourced equally to the outputs. |
|
|
J, R |
Marchand Balun |
390 |
13500 |
• Planar Marchan Baluns. • Available as LTCC or MMIC. • Operate at much higher and wider frequency bands compared to transmission line transformers. • Provide DC isolation between primary and secondary windings, and the potential to allow for DC bias. |
• Config J is for a standard Marchand Balun and the secondary winding is DC grounded. • Config R has the secondary winding decoupled from DC ground, which allows for DC biasing to be applied to the next stage without requiring a decoupling capacitor. |
|
Q |
Impedance matching |
DC |
2500 |
• 50 to 75 Ohm impedance matching transmission line transformer. |
|
Transformer Technology & Guidelines
Beyond 1 GHz, capacitive coupling is much greater than magnetic induction in terms of signal transmission. As this effect is a function of size, there are frequency limitations based on the physical size of a core & wire transformer. The size of the wire and core are also major factors in determining the power handling of these transformers. Power handling is also largely limited by the saturation of the ferrite core, which is why these types of transformers are typically limited to less than 1W of power.
Core & wire transformers are typically made of heavy metals and are relatively bulky compared to planar RF transformer technologies. Therefore, applications that require compact size devices may be better served using LTCC or MMIC transformers.