CMM0015-BD_09 Datasheet, PDF(8/10 Page) Mimix Broadband

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CMM0015-BD_09 Datasheet, PDF (8/10 Pages) Mimix Broadband – Power Amplifier

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2.0-22.0 GHz GaAs MMIC

Power Amplifier

September 2009 - Rev 22-Sep-09

CMM0015-BD

App Note [1] Biasing - As shown in the bonding diagram, this device

operates using a self-biased architecture and only requires one drain bias.

Bias is nominally Vd=12.0 V, Id=350 mA. For additional assistance in setting

current via source resistor, see source resistance table below.

App Note [2] Bias Arrangement - Each DC pad (Vd) needs to have DC

bypass capacitance (~100-200 pF) as close to the device as possible.

Additional DC bypass capacitance (~0.01 uF) is also recommended.

Additionally, to achieve the required broadband decoupling network a

high-Q Drain bias inductor with high-Q bypass capacitor is needed. The

proper network is necessary in order to bring Drain bias into the device

with minimal impact on RF performance.The high-Q inductor is typically an air

coil that can be purchased from an air coil manufacturer (Microwave Components or Piconics for example). The air coil needs to have minimum

current handling capability, thus planned operating current needs to be defined and considered before defining actual air coil to be used. Mimix

recommends 1.4 mil diameter gold wire and 4 turns as a starting point and may need to be optimized based on the actual application. Self-

resonance of the bias inductor causes degradation in performance at both the low and high ends of the band.The self resonance is sensitive to

spacing between turns and number of turns used. For example, the more turns in the Drain bias inductor the lower the self-resonant frequency of

the inductor creating high end RF performance degradation.The opposite is true for a smaller number of turns. In terms of coil attachment to

MMIC device (wedge bond tool method), cut coil leads to desired length, use tweezers or wedge bond tip (press on wire to pick up) to place coil

for bonding. Make first bond on MMIC die bond pad using wedge bonder tool. Move coil lead as necessary and make second and final bond to

bypass capacitor with wedge bond tool using same method as first bond.

Current Select - At times the need to balance performance against system

power budgets forces a trade off between bias current, gain, P1dB, or other

parameters. This note includes information on how to use the built-in binary

bias ladder to adjust the currents enabling this trade off. The bias is controlled

by the self bias resistor network in the bottom right corner of the die. These

resistors have binary relative values so that you can step the current from a

minimum to a maximum with multiple different bias options available along

the way. The infinity option is not useful as there is no current flow with all

resistors open. Using the information from the current select table shown

here allows the user to set the resistors adjusting the current up or down

from a nominal value. In addition, the table can be used to estimate how to

CMM0015 - Source Resistance Table

Left

Center Corner

4.5

3.5

Net R Delta Current

Infinity

6.00

-275

4.50

-225

3.50

-175

2.57

-100

2.21

-75

1.97

-50

1.48

Max

make a change with minimum trial and error. The net result is that the current

can be adjusted over a wide range with incremental control.

Bonding Substrate - If you are concerned about dialing in the exact current

or making fine adjustments to the bias point it is recommended that a

bonding substrate, like the one shown here, be used. The purpose is to allow

the chip to substrate wire bonds to be left intact and not to be used for

adjustments. The bond wires that go from the substrate to ground are then

added or subtracted to tune the bias as necessary.

App Note [3] Material Stack-Up â In addition to the practical aspects of bias and

bias arrangement, device base material stack-up also must be considered for best

thermal performance. A well thought out thermal path solution will improve

overall device reliability, RF performance and power added efficiency.The photo

shows a typical high power amplifier carrier assembly. The material stack-up for

this carrier is shown below. This stack-up is highly recommended for most reliable

performance however, other materials (i.e. eutectic solder vs epoxy, copper tungsten/copper moly rib, etc.) can be considered/possibly used but

only after careful review of material thermal properties, material availability and end application performance requirements.

MMIC, 3mil

Diemat DM6030HK Epoxy, ~1mil

MOLY Rib, 5mil, Au plated

Alumina Substrate

AuSn Eutectic Solder

Copper Block

MOLY Carrier, 25mil

Au plated

Mimix Broadband, Inc., 10795 Rockley Rd., Houston, Texas 77099

Tel: 281.988.4600 Fax: 281.988.4615 mimixbroadband.com

Page 8 of 10

Export of this item may require appropriate export licensing from the U.S. Government. In purchasing these parts, U.S. Domestic customers accept

their obligation to be compliant with U.S. Export Laws.

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