SKY77336 Power Amplifier Module

APPLICATION NOTE
SKY77336 Power Amplifier Module – Evaluation Information
Applicability: SKY77336 Power Amplifier Modules
INTRODUCTION
The latest Skyworks GSM Power Amplifier Modules (PAM) featuring the new CMOS Collector Voltage Amplitude Controller (COVAC)
provides high level integration, high efficiency, and ease of application in a new smaller package. These PAMs support GMSK and Class
12 GPRS multi-slot operations and EDGE Polar Modulation. The new CMOS control circuit provides envelope amplitude control and
reduces sensitivity to input drive, temperature, power supply, and process variations.
A Skyworks COVAC PAM consists of an InGaP Power Amplifier (PA) lineup block, a CMOS bias control block, impedance matching and
harmonic filtering circuits. Two separate Heterojunction Bipolar Transistor (HBT) PA lineups are embedded in a single Gallium Arsenide
(GaAs) die to support the GSM850/900 and the DCS1800 and PCS1900 bands. The CMOS block provides the internal PAC control
functions. This Application Note describes the functionality and layout of the evaluation board, and applications instructions for the
SKY77336.
Finally, for further information, Figure 8 through Figure 11 show the individual board layers.
Figure 1. SKY77336 Functional Block Diagram
GSM/GPRS Operation
For GMSK transmit operation, set TxEN input logic high. Select the desired TX band by setting BS low for CEL/EGSM or high for DCS/PCS.
VAPC is a pulsed input with a specific ramp profile that controls the module output power. The requirements for the VAPC waveform
properties are discussed in more detail on page 3.
VAPC Filter
A first-order RC network on the VAPC line may be required during evaluation of GMSK operation to filter noise introduced by the baseband
DAC or an external waveform generator. The filter should be so designed as to not slow down the power mask timing requirements. The
recommended RC network is shown in Figure 7 (see Note 1 for RC values). This filter is suitable for GMSK operation but will not support
EDGE operation.
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APPLICATION NOTE
SKY77336 EVALUATION BOARD INFORMATION
Depending on the operating characteristics of the baseband DAC, the RC network must be carefully designed or eliminated. Increasing the
resistor value might have a negative impact on voltage drop, and consequently, PA output power. The loop bandwidth requirement of the
Polar Loop Transmitter architecture must be considered if such a filter is needed.
Power Control Scheme:
PA output power is controlled by an integrated power control scheme that limits power at the collector by limiting collector voltage.
Figure 2 is a simplified schematic of a control scheme that senses collector voltage, compares it to the external VAPC signal, and then sets
the required bias voltage at the PA.
Figure 2. SKY77336 Power Control Scheme – GMSK Mode
Transmitter Calibration for GMSK Operation
During the handset development phase, a simple one-time process is executed to derive the ramp percentage coefficients to optimize
spectral performance. A raised-cosine ramp profile is recommended so the resulting output voltage envelope will have a raised-cosine
shape.
To meet specifications, all handsets must be calibrated during the manufacturing process. Data from a limited number of power
measurements are saved along with the ramp coefficient percentages to generate actual digital codes used by the baseband DAC to drive
the VAPC input of the PAM.
During handset operation in the field, the base station will request a specific power level. The baseband chip in the handset will retrieve
the digital codes stored in non-volatile memory and convert them to the corresponding analog value to drive the VAPC input of the PAM.
General VAPC DAC Ramp Profile Development
The following subsections outline the general process for ramp profile development and handset calibration. The actual steps will depend
on the manufacturer.
Timing Diagram
Timing of the burst is critical to handset performance as it directly affects the time mask and switching transients. To optimize handset
performance, Skyworks strongly recommends the timing diagram in Figure 3.
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SKY77336 EVALUATION BOARD INFORMATION
APPLICATION NOTE
Figure 3. Transmit Timing Diagram for SKY77336 Single GMSK Slot Timing
The recommended VAPC ramp profile and TxEN timing shown in Figure 4 specifies the following:
The VSTART and VFINAL pedestal values of the VAPC ramp shall be set to a level of 200 mV and duration of ½ symbol (~2 μs) each.
The relationship of TxEN signal timing to VAPC is crucial to the GSM system operation. This control signal must be properly timed to
optimize system performance. It is asserted 3.5 symbols prior to the first bit.
Raised-cosine ramp-up and ramp-down periods are 10 μs and 14 μs, respectively. Notice that the peak value timing at the end of the
ramp-up is set to 1 μs before bit 1. This compensates for the delay of the PAC VAPC filter. For the ramp-down, the first value at the
beginning of the ramp-down is set to 99% of the peak value. This also compensates for the delay of the filter.
The useful burst period where information resides is approximately 543 μs.
Depending on the baseband chip driving VAPC and other system design considerations, there are approximately 10 quarter-symbol or 5
half-symbol discrete DAC steps on the rising edge and falling edge of the burst. The actual rate of sending these DAC values to the FEM is
dependent on the baseband manufacturer.
The equations based upon the raised-cosine ramp profile are as follows:
VAPC_UP = 0.5(VPEAK – VSTART) [1 + Cos ( t / T + )] + VSTART
VAPC_DOWN = 0.5(VPEAK – VFINAL) [1 + Cos ( t / T)] + VFINAL
Where:
t = step number (i.e. 0, 1, 2…10)
T= total number of steps (T = 10)
VSTART ~ 0.2 V
VFINAL ~ 0.2 V
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APPLICATION NOTE
SKY77336 EVALUATION BOARD INFORMATION
Figure 4. Recommended RAMP Profile for Single GMSK Slot Timing
Ramp Profile Development Steps
Perform a mid-band GSM calibration on each handset. From a limited number of measurements of output power (POUT) at the antenna
port, extrapolate a general peak POUT versus VAPC curve for that particular handset. Typically, the curve can be generated using two
measured data points and the following equation:
POUT (peak) = M log (VAPC – VT) + POFF
Where:
M defines the slope of the control response (dBm / V)
VT corresponds to VAPC at loop closure (V)
POFF defines the Y-intercept (dB)
At this point, VAPC levels for any power control level (PCL) requested by the base station can be predicted from the curve. An example of
the curve can be seen in Figure 5.
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APPLICATION NOTE
Figure 5. Example of POUT (peak) vs. VAPC (peak)
LOGIC AND INPUT SETTINGS
Table 1. SKY77336 Control Logic
Mode
Input Control Bits
TxEN
BS
Standby
0
0
Tx_LOW BAND
1
0
Tx_HIGH BAND
1
1
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APPLICATION NOTE
SKY77336 EVALUATION BOARD INFORMATION
SKY77336 Evaluation Board
The evaluation board assembly drawing in Figure 6 shows the placement of board components and their designations. The circuit
schematic of the evaluation board in Figure 7 illustrates the interconnections and board components in relation to the SKY77336 Power
Amplifier Module. Where appropriate, components not actually installed on the latest board revision are highlighted on the evaluation
board drawing, the circuit schematic, and in the component bill of material. Such components are often included in the initial board
design to provide maximum test flexibility. See Table 2 for the interface connector pin numbering convention and the pin signal
descriptions. Table 3 lists the bill of material with the component descriptions and value ratings. Finally, for further information, Figure 8
through Figure 11 shows the individual board layers.
Figure 6. SKY77336 Evaluation Board
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APPLICATION NOTE
Figure 7. SKY77336 Evaluation Board Schematic
Table 3. SKY77336 EVALUATION BOARD BILL OF MATERIAL 1
Table 2. P1 SIGNAL DEFINITIONS
Pin
Signal
Pin
Designator
Signal
Description
J1, J2, J3, J4, J5
CONN SMA END LAUNCH JACK TAB CONTACT GOLD 0.062"
P1
CONNECTOR, WAFER ASSEMBLY, 12-PIN, POST LENGTH = 0.53"
BS
C2
CAPACITOR, TANTALUM, 10 μF, 16 V, ±10%, B CASE SIZE
DCDC_IN
C5
CAPACITOR, CERAMIC, 0.1 μF, X7R, 50 V, ±10%, 0402
C6
CAPACITOR, CERAMIC, 1000 pF, X7R, 50 V, ±10%, 0402
R2, R3
RESISTOR, 0402, ZERO OHMS, 0.063 W, 0402
P1.1
N/C
P1.7
N/C
P1.2
GND
P1.8
P1.3
VBATT
P1.9
P1.4
GND
P1.10 TxEN
P1.5
VBATT_SNS
P1.11 GND
P1.6
GND
P1.12 VAPC
1
R1, C1, C3, C4, C7, C8 ARE NOT INSTALLED. C1 AND R1 (0402 CASE SIZE) CAN BE INSTALLED FOR ADDITIONAL VAPC
FILTERING. C3 (0603 CASE SIZE) AND C4 (B CASE SIZE) CAN BE INSTALLED FOR ADDITIONAL VBATT FILTERING. C7 AND C8
(0603 CASE SIZE) ARE FOR FUTURE USE.
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SKY77336 EVALUATION BOARD INFORMATION
APPLICATION NOTE
Figure 8. SKY77336 Evaluation Board Layer 1
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SKY77336 EVALUATION BOARD INFORMATION
APPLICATION NOTE
Figure 9. SKY77336 Evaluation Board Layer 2
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APPLICATION NOTE
SKY77336 EVALUATION BOARD INFORMATION
Figure 10. SKY77336 Evaluation Board Layer 3
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APPLICATION NOTE
Figure 11. SKY77336 Evaluation Board Layer 4
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APPLICATION NOTE
SKY77336 EVALUATION BOARD INFORMATION
SKY77336 PHONE BOARD APPLICATION CIRCUIT
Layout Guidelines for Battery Bypassing
While phone board layout is a complex issue, one key area is supply decoupling. As the timing diagram in Figure 3 shows, the transient
current for VBATT will be supported by the nearby capacitance. The VBATT line of the FEM requires low frequency bypassing capacitance. In
modern communication systems, a GSM PA draws rapid pulses of current that can cause a significant transient during the transmission.
This might affect the output power mask at high power levels. Most lab supplies are not suited for digital communications and do not
emulate the phone board battery condition. Hence, in some cases a higher value capacitor of 68 μF may be required.
In the phone board, battery ESR will reduce the transient voltage pulse and should not require more than a 10 μF bypass capacitor. The
bypass capacitor should be a good quality ceramic or tantalum capacitor.
Figure 12. Application Layout Diagram for SKY77336
Table 4. Pad Names and Functions
Pad
1
Signal
Function
1
DCS/PCS_IN Input TX signal 1800/1900MHz
2
BS
Band Select
3
Tx_EN
Enable
4
VBATT
Battery Supply Voltage
5
VAPC
Input modulating signal / power control
8
GSM_IN
Input TX signal 850/900MHz
9
GSM_OUT
Output TX signal 850/900MHz
16
DCS_OUT
Output TX signal 1800/1900MHz
Pads 7, 10–12, 14, 15 are GROUND pads; pads 6, 13 are No Connect
Figure 13. SKY77336 Pad Configuration and Names – Top View
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Ordering Information
Model Number
Manufacturing Part Number
SKY77336 Evaluation Board
TW16-D490-021
Package
Operating Temperature
–25 °C to +100 °C
Revision History
Revision
A
Date
September 9, 2008
Description
Initial Release
References
Skyworks Data Sheet: SKY77336 Power Amplifier Module for Quad-Band GSM / GPRS, Document Number 200780
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