RFMD RF2948BPCBA

RF2948B
0
2.4GHz SPREAD-SPECTRUM TRANSCEIVER
Typical Applications
• IEEE 802.11b WLANs
• High Speed Digital Links
• Wireless Residential Gateways
• Wireless Security
• Secure Communication Links
• Digital Cordless Telephones
2 PLCS
0.10 C A
IG
N
S
Product Description
-A-
2.50 TYP.
E
S
2 PLCS
0.10 C B
2 PLCS
0.10 C A
9Si Bi-CMOS
SiGe HBT
InGaP/HBT
0.05
0.00
12°
MAX
-B-C-
SEATING
PLANE
2.37 TYP.
4.75 SQ.
0.10 M C A B
0.60
0.24
TYP.
0.30
0.18
2
Pin 1 ID
R.20
Shaded lead is pin 1.
3.45
SQ.
3.15
W
N
E
GaAs HBT
0.70
0.65
Dimensions in mm.
0.50
0.30
0.50
Optimum Technology Matching® Applied
Si BJT
0.05 C
0.90
0.85
2 PLCS
0.10 C B
3
D
The RF2948B is a monolithic integrated circuit specifically designed for direct-sequence spread-spectrum systems operating in the 2.4GHz ISM band. The part
includes: a direct conversion from IF receiver with variable gain control; quadrature demodulator; I/Q baseband
amplifiers; and, on-chip programmable baseband filters.
For the transmit side, a QPSK modulator and upconverter
are provided. The design reuses the IF SAW filter for
transmit and receive reducing the number of SAW filters
required. Two-cell or regulated three-cell (3.6V maximum) battery applications are supported by the part. The
part is also designed to be part of a 2.4GHz chipset consisting of the RF2494 LNA/Mixer, one of the many RFMD
high-efficiency GaAs HBT PA’s and the RF3000 Baseband Processor.
5.00 SQ.
Package Style: QFN, 32-Pin, 5x5
GaAs MESFET
Si CMOS
Features
SiGe Bi-CMOS
VREF 1
VCC2
BW CTRL
DCFB Q
DCFB I
VREF1 BUF
Q OUT
• 45MHz to 500MHz IF Quad Demod
RX VGC
FO
R
GaN HEMT
32
31
30
29
28
27
26
25
• On-Chip Variable Baseband Filters
• Quadrature Modulator and Upconverter
BW
Control
• 2.7V to 3.6V Operation
DC
Feedback
N
O
T
PD 1
RX EN 2
RX IF BIAS 3
• Part of IEEE802.11b Chipset
gm-C
LPF
Logic
DC
Feedback
REF
• 2.4GHz PA Driver
gm-C
LPF
VCC1 4
24 I OUT
RX IF IN 5
TX
Bias
23 VCC4
gm-C
LPF
TX IF IN 6
VCC9 7
22 TXQ DATA
21 TXQ BP
Ordering Information
Σ
gm-C
LPF
TX VGC 8
÷2
Phase
Splitter
RF2948B
RF2948BTR13
RF2948B PCBA
20 TXI DATA
19 TXI BP
18 IF1 OUT+
2.4GHz Spread-Spectrum Transceiver
2.4GHz Spread-Spectrum Transceiver (Tape & Reel)
Fully Assembled Evaluation Board
17 IF1 OUT15
16
RF OUT
VCC5
14
RF LO
13
PA IN
12
PA OUT
11
VCC6
10
VCC8
IF LO
9
Functional Block Diagram
RF Micro Devices, Inc.
7628 Thorndike Road
Greensboro, NC 27409, USA
Tel (336) 664 1233
Fax (336) 664 0454
http://www.rfmd.com
NOT FOR NEW DESIGNS
Rev A6 040930
11-239
RF2948B
Absolute Maximum Ratings
Parameter
Refer to “Handling of PSOP and PSSOP Products” on page 16-15 for
special handling information.
Rating
Unit
-0.5 to +3.6
-0.5 to +3.6
+12
+5
-40 to +85
-40 to +150
VDC
VDC
dBm
dBm
°C
°C
MSL JEDEC level 3 at 240oC
Specification
Min.
Typ.
Max.
Parameter
Refer to “Soldering Specifications” on page 16-13 for special soldering information.
Caution! ESD sensitive device.
RF Micro Devices believes the furnished information is correct and accurate
at the time of this printing. However, RF Micro Devices reserves the right to
make changes to its products without notice. RF Micro Devices does not
assume responsibility for the use of the described product(s).
IG
N
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Supply Voltage
Control Voltages
Input RF Level
LO Input Levels
Operating Ambient Temperature
Storage Temperature
Unit
Condition
T=25 °C, VCC =3.0V, Freq=374MHz,
RBW =10kΩ
Overall Receiver
Cascaded Noise Figure
Cascaded Input IP3
Cascaded Input IP3
IF LO Leakage
Quadrature Phase Variation
374
50
115
-68
0
Gain
65
Noise Figure
IF Input Impedance
4.5
70
5.5
515-j994
MHz
dB
dB
dB
dBµV
dBµV
dBm
°
2
dB
VPP
%
7.5
dB
+1
W
IF AMP and Quad Demod
±3
0
1.2
N
E
Quadrature Amplitude Variation
Output P1dB
Distortion
500
76
3
35.0
RX VGC =1.2V
RX VGC =2.0V
Varies with gain.
VGC <1.2V
VGC>2.0V
f=374MHz, LO Power=-10dBm
With expected LO amplitude and harmonic
content.
E
S
45
65
0
5.5
D
RX Frequency Range
Cascaded Voltage Gain
dB
Ω
1.4<RX VGC <1.8V
At 0.70VPP output level.
VGC =1.95V=min gain
VGC =1.25V max gain
Single Sideband, max gain.
Single-ended. 374MHz
VREF1-15
2
700
VREF1
1
FO
THD
Output Voltage
DC Output Voltage
R
RX Baseband Amplifiers
At 0.707VP-P output level
RL >5kΩ, CL <15pF
VREF1+15
%
mVPP
mV
10
35
MHz
5th order Bessel LPF.
Set by BW CTRL (RBW)
±10
0.1
±30
dB
%
RX Baseband Filters
Baseband Filter 3dB Bandwidth
N
O
T
Passband Ripple
Baseband Filter 3dB
Frequency Accuracy
Group Delay
Group Delay
Baseband Filter
Ultimate Rejection
Output Impedance
11-240
15
ns
400
>80
ns
dB
20
Ω
At 35MHz, increasing as bandwidth
decreases.
At 2MHz.
Designed to drive>5kΩ, <15pF load.
Rev A6 040930
RF2948B
Specification
Min.
Typ.
Max.
Parameter
Unit
Condition
Transmit Modulator and
LPF
0
1
15
Group Delay
Ultimate Rejection
Input Impedance
Input AC Voltage
Input P1dB
Input DC Offset Requirement
IF Frequency Range
Differential Output Resistance
400
>80
3
100
200
1.6
45
1.7
1.8
500
22
-18
-26
-30
FO
R
VGA Gain Range
VGA Control Voltage Range
VGA Gain Sensitivity
VGA Input Impedance
RF Mixer Output Impedance
VGA/Mixer Conversion Gain
VGA/Mixer Output Power
N
E
Harmonic Outputs
Transmit VGA and
Upconverter
ns
dB
kΩ
mVp-p
mVp-p
V
MHz
kΩ
pF
pF
±3
±1
W
Carrier Output
dB
MHz
dB
ns
E
S
0.436
0.4
0
0
0.0185
D
Differential Output Capacitance
Shunt Output Capacitance
I/Q Phase Balance
I/Q Gain Balance
Conversion Transconductance
Any setting
5th order Bessel LPF, Set by BW CTRL
At 35MHz, increasing as bandwidth
decreases.
At 2MHz.
Single-ended
Linear, Single-ended.
Single-ended.
For correct operation.
dB
S
dBc
Between output pins. Open collector when
TX on, Hi Z when TX off
Between output pins.
From each pin to ground.
Single-ended voltage input to differential output current conversion gain.
Without external offset adjustments.
374MHz. Compared to modulated signal,
100mVP-P input.
dBc
17
1.0 to 2.0
17
515-j994
50
-3 to +14
-9
dB
V
dB/V
Ω
Ω
dB
dBm
-4
dBm
Positive Slope
374MHz
With matching elements.
With 50Ω match on the output.
1dB compression - Single Sideband,
TX GC=1.0V. (Desired signal power)
1dB compression - Single Sideband,
TX GC=2.0V. (Desired signal power)
N
O
T
VGA/Mixer Output Power
35
0.1
IG
N
S
Filter Gain
Baseband Filter 3dB Bandwidth
Passband Ripple
Group Delay
Rev A6 040930
11-241
RF2948B
Parameter
Specification
Min.
Typ.
Max.
Unit
6
9
12
50
50
dBm
dB
dBm
Ω
Ω
Condition
Transmit Power Amp
Linear Output Power
Gain
Output P1dB
Output Impedance
Input Impedance
10
Nominal
Nominal
Power Down Control
VCC -0.3V
Logical Controls “OFF”
Control Input Impedance
RX VGC Response TIme
RX EN Response TIme
TX EN Response TIme
VPD to RX Response TIme
VPD to TX Response TIme
-0.3
0
>1
200
2
330
1.33
50
VCC +0.3V
V
0.3
V
MΩ
ns
µs
ns
ms
µs
1050-j1200
-10
RF LO Input
33-j110
-10
2000
VREF1 Buffered
Power Supply
mA
mV
V
V
1.7
2.7
3.3
3.6
FO
N
O
T
11-242
Ω
dBm
MHz
1
VREF1+10
1.8
R
Voltage
Total Current Consumption
Sleep Mode Current
PA Driver Current
RX Current
BW (MHz)
9
12-20
20-30
TX Current
BW (MHz)
9
12-20
20-30
0
2400
VREF1-10
1.6
N
E
Source/Sink Current
Output Voltage
VREF1
Ω
dBm
MHz
W
Input Impedance
Input Power Range
Input Frequency
0
1000
D
-15
90
Full step in gain, to 90% of final output level.
I/Q output VALID
To IF output VALID
To I/Q output VALID
To IF output VALID
The IF LO is divided by 2 and split into
quadrature signals to drive the frequency
mixers.
f=748MHz
peak
(2x IF Frequency)
E
S
IF LO Input
Input Impedance
Input Power Range
Input Frequency
Voltage supplied to the input, not to exceed
3.6V.
Voltage supplied to the input.
IG
N
S
Logical Controls “ON”
µA
mA
1
18
65
70
110
85
mA
mA
mA
95
105
115
136
mA
mA
mA
f=2.04GHz unmatched.
VCC =3.3V, Baseband BW 1MHz to 40MHz
PD=0, RX EN=1
TX EN=1
Rev A6 040930
RF2948B
Pin
1
Function
PD
Description
Interface Schematic
This pin is used to power up or down the transmit and receive baseband sections. A logic high powers up the quad demod mixers, TX and
RX GmC LPF’s, baseband VGA amps, data amps, and IF LO buffer
amp/ phase splitter. A logic low powers down the entire IC for sleep
mode. Also, see State Decode Table.
VCC
10 kΩ
Pins
3, 4, 5
ESD
To
Logic
3
4
5
RX IF BIAS
VCC1
RX IF IN
6
TX IF IN
IF input for receiver section. Must have DC-blocking cap. The capacitor See pin 6.
value should be appropriate for the IF frequency. For half-duplex operation, connect RX IF IN and TX IF IN signals together after the DC blocking caps, then run a transmission line from the output of the IF SAW.
AC coupling capacitor must be less than 150pF to prevent delay in
switching RX to TX/TX to RX.
Input for the TX IF signal after SAW filter. External DC-blocking cap
IF
required. For half-duplex operation, connect RX IF IN and TX IF IN sigSAW
nals together after the DC-blocking caps, then run a transmission line
Filter
from the output of the IF SAW. AC coupling capacitor must be less than
150pF to prevent delay in switching RX to TX/TX to RX.
D
Pin 8
Gain control setting for the transmit VGA. Positive slope.
IF LO input. Must have DC-blocking cap. The capacitor value should be
appropriate for the IF frequency. LO frequency=2xIF. Quad
mod/demod phase accuracy requires low harmonic content from IF LO,
so it is recommended to use an n=3 LPF between the IF VCO and IF
LO. This is a high impedance input and the recommended matching
approach is to simply add a 100Ω shunt resistor at this input to constrain the mismatch.
Recommended Matching
Network for IF LO
C2
150 pF
IF VCO
IF LO
Pin 9
R
100 Ω
Power supply for IF LO buffer and quadrature phase network.
Power supply for transmitter bias generator.
FO
VCC8
VCC6
PA OUT
N
O
T
10
11
12
Rev A6 040930
DC
Block Pin 7
50 Ω µstrip
Power supply for the TX 15dB gain amp and TX VGA.
W
VCC9
TX VGC
IF LO
See pin 1.
Power supply for RX VGA amplifier, IC logic and RX references.
N
E
7
8
9
Enable pin for the receiver 15dB gain IF amp and the RX VGA amp.
Powers up all receiver functions when PD is high, turns off the receiver
IF circuits when low. Also, see State Decode Table.
When this pin is a logic “high”, the device is in receive mode. When this
pin is a logic “low”, the device is in transmit mode.
Shunt resistor of 23.7±1% to ground. Biases IF AMPS.
IG
N
S
RX EN
E
S
2
This is the output transistor of the power amp stage. It is an open collector output. The output match is formed by an inductor to VCC, which
supplies DC and a series cap.
VCC
CBYP
22 nF
L
Power
Amp
Output
C
PA OUT
From
TX RF
Image Filter
14 mA
PA IN
Bias
11-243
RF2948B
Pin
13
Function
PA IN
14
VCC5
Description
Interface Schematic
Input to the power amplifier stage. This is a 50Ω input. Requires DCblocking/tuning cap.
Supply for the RF LO buffer, RF upconverter and amplifier.
See pin 12.
VCC
VCC
CBYP
22 nF
To TX RF
Image Filter
CBYP
22 nF
VCC5
RF OUT
From
TX VGA
12 mA
VB
IG
N
S
RF LO
From
RF VCO
16
RF OUT
17
IF1 OUT-
Single-ended LO input for the transmit upconverter. External matching See pin 14.
to 50Ω and a DC-block are required.
Upconverted Transmit signal. This 50Ω output is intended to drive an
See pin 14.
RF filter to suppress the undesired sideband, harmonics, and other outof-band mixer products.
The inverting open collector output of the quadrature modulator. This
pin needs to be externally biased and DC isolated from other parts of
IF1 OUT+
the circuit. This output can drive a Balun with IF1 OUT+, to convert to
unbalanced to drive a SAW filter. The Balun can be either broadband
(transformer) or narrowband (discrete LC matching). Alternatively, just
IF1 OUT+ can be used to drive a SAW single-ended with an RF choke
(high Z at IF) from VCC to IF1 OUT-.
E
S
RF LO
D
15
CBLOCK
22 pF
IF1 OUT+
The non-inverting open collector output of the quadrature modulator.
This pin needs to be externally biased and DC isolated from other parts
of the circuit. This output can drive a Balun with IF1 OUT-, to convert to
unbalanced to drive a SAW filter. The Balun can be either broadband
(transformer) or narrowband (discrete LC matching). Alternatively, just
IF1 OUT+ can be used to drive a SAW single-ended with an RF choke
(high Z at IF) from VCC to IF1 OUT+.
19
TXI BP
20
21
TXI DATA
TXQ BP
This is the in-phase modulator bypass pin. A 10nF capacitor to ground
is recommended.
I input to the baseband 5 pole Bessel LPF for the transmit modulator.
22
23
24
TXQ DATA
VCC4
I OUT
25
Q OUT
26
VREF1 BUF
27
DCFB I
28
DCFB Q
29
BW CTRL
30
VCC2
See pin 17.
R
This is the quadrature phase modulator bypass pin. A 10nF capacitor
to ground is recommended.
Q input to the baseband 5 pole Bessel LPF for the transmit modulator.
FO
N
O
T
11-244
N
E
W
18
IF1 OUT-
Power supply for quadrature modulator.
Baseband analog signal output for in-phase channel.
700mVP-P linear output.
Baseband analog signal output for quadrature channel.
700mVP-P linear output.
Buffered version of the VREF1 output. See pin 31.
Sink/Source current <1mA.
DC feedback capacitor for in-phase channel. Requires capacitor to
ground. (22nF recommended)
DC feedback capacitor for quadrature channel. Requires decoupling
capacitor to ground. (22nF recommended)
This pin requires a resistor to ground to set the baseband LPF bandwidth of the receiver and transmit GmC filter amps.
Supply for the I and Q baseband and GmC filters. This pin should be
bypassed with a 10nF capacitor.
Rev A6 040930
RF2948B
Pin
31
Function
VREF 1
32
Pkg
Base
RX VGC
Interface Schematic
This is a bypass pin for the bias circuits of the GmC filter amps and for
I/Q inputs. No current should be drawn from this pin (<10µA). 1.7V
nominal.
Receiver IF and baseband amp gain control voltage. Negative slope.
Ground for all circuitry in the device. A very low inductance from the
base to the PCB groundplane is essential for good performance. Use
an array of vias immediately underneath the device.
This diode structure is used to provide electrostatic discharge protection to 3kV using the Human body model. The following pins are protected: 1-4, 7, 8, 10, 19-32.
VCC
N
O
T
FO
R
N
E
W
D
E
S
IG
N
S
ESD
Description
Rev A6 040930
11-245
RF2948B
Input Pins
PD
RX EN
0
x
1
1
1
0
State Decode Table
Sleep Mode
Receive Mode
Transmit Mode
Internally Decoded Signals
BB EN
RXIF EN
TXRF EN
0
0
0
1
1
0
1
0
1
NOTES
BB_EN Enables:
Quad Demodulator mixers
Baseband Amps and gm-C LPF’s
IF LO buffer/phase splitters
RXIF_EN Enables:
RX IF VGA amplifiers
TXRF_EN Enables:
E
S
Front-end IF amplifier (RX)
IG
N
S
TX_LPF’s and buffers
TX VGA
D
Front-end IF amplifier (TX)
RF upconverter and buffer
W
PA driver
RF LO buffer
N
O
T
FO
R
N
E
Quad Modulator mixers
11-246
Rev A6 040930
RF2948B
RX VGC
VREF 1
VCC2
BW CTRL
DCFB Q
DCFB I
VREF1 BUF
Q OUT
Detailed Functional Block Diagram
32
31
30
29
28
27
26
25
IG
N
S
BW
Control
DC
Feedback
PD 1
RX EN 2
gm-C
LPF
Logic
RX IF BIAS 3
DC
Feedback
E
S
REF
gm-C
LPF
24 I OUT
D
VCC1 4
TX
Bias
W
RX IF IN 5
N
E
TX IF IN 6
VCC9 7
gm-C
LPF
Σ
gm-C
LPF
R
Phase
Splitter
20 TXI DATA
FO
19 TXI BP
18 IF1 OUT+
10
11
12
13
14
15
16
IF LO
VCC8
VCC6
PA OUT
PA IN
VCC5
RF LO
RF OUT
17 IF1 OUT-
9
N
O
T
Rev A6 040930
22 TXQ DATA
21 TXQ BP
TX VGC 8
÷2
23 VCC4
11-247
RF2948B
Theory of Operation
RECEIVER
RX IF AGC/Mixer
Being essentially high impedance, RX IF IN responds
to the input voltage (rather than power), and amplifies
that voltage by the gain specified in the datasheet, then
presents the output voltage at a high impedance (after
downconversion). For characterization purposes, a
50Ω shunt resistor is placed on the IF signal path,
before AC-coupling to the input. A 50Ω signal source is
applied directly across the shunt resistor, through a
coaxial test lead. The signal source sees the shunt
resistor and therefore a low SWR. Voltage gain is then
simply the ratio of the output voltage to the input voltage.
N
E
R
The IF to BB mixers are double-balanced, differential
in, differential out, mixers with negligible conversion
gain. The LO for each of these mixers is shifted 90° so
that the I and Q signals are separated in the mixers.
IG
N
S
E
S
IF LO Buffer
The IF LO input has a limiting amplifier before the
phase splitting network to amplify the signal and help
isolate the VCO from the IC. Also, the LO input signal
must be twice the desired intermediate frequency. This
simplifies the quadrature network and helps reduce the
LO leakage onto the RX_IF input pin (since the LO
input is now at a different frequency than the IF). The
amplitude of this input needs to be between -15dBm
and 0dBm. Excessive IF LO harmonic content affects
phase balance of the modulator and demodulator so it
is recommended that IF LO harmonics be kept below
-30dBc.
N
O
T
FO
RX Baseband Amps, Filters, and DC Feedback
At baseband frequency, there are fully integrated gm-C
low pass filters to further filter out-of-band signals and
spurs that get through the SAW filter, anti-alias the signal prior to the A/D converter, and to band-limit the signal and noise to achieve optimal signal-to-noise ratio.
The 3dB cut-off frequency of these low pass filters is
programmable with a single external resistor, and continuously variable from 1MHz to 35MHz. A five-pole
Bessel type filter response was chosen because it is
optimal for data systems due to its flat delay response
and clean step response. Butterworth and Chebychev
type filters ring when given a step input making them
less ideal for data systems. The filter outputs drive the
linear 700mVPP signal off-chip.
LO INPUT BUFFERS
RF LO Buffer
The RF LO input has a limiting amplifier before the
mixer on both the RF2494 (RX) and RF2948B (TX).
This limiting amplifier design and layout is identical on
both ICs, which will make the input impedance the
same as well. Having this amplifier between the VCO
and mixer minimizes any reverse effect the mixer has
on the VCO, expands the range of acceptable LO input
levels, and holds the LO input impedance constant
when switching between RX and TX. The LO input
power range is -18dBm to +5dBm, which should make
it easy to interface to any VCO and frequency synthesizer.
D
W
The front end of the IF AGC starts with a single-ended
input and a constant gain amp of 15dB. This first amp
stage sets the noise figure and input impedance of the
IF section, and its output is taken differentially. The rest
of the signal path is differential until the final baseband
output, which is converted back to single-ended. Following the front end amp are multiple stages of variable gain differential amplifiers, giving the IF signal
path a gain range of 4.0dB to 70.0dB. The noise figure
(in max gain mode) of the IF amplifiers is 5dB, which
should not degrade the system noise figure.
DC feedback is built into the baseband amplifier section to correct for input offsets. Large DC offsets can
arise when a mixer LO leaks to the mixer input and
then mixes with itself. DC offsets can also result from
random transistor mismatches. A large external capacitor is needed for the DC feedback to set the high pass
cutoff.
11-248
Rev A6 040930
RF2948B
IG
N
S
+6dBm PA Driver
The SSB output of the upconverter is -6dBm of linear
power. The image filter should have at most 4dB of
insertion loss while removing the image, LO, 2LO and
any other spurs. The filter output should supply the PA
driver input -10dBm of power.
The PA driver is a one-stage class A amplifier with
10dB gain and capable of delivering 6dBm of linear
power to a 50Ω load, and has a 1dB compression
point of 12dBm. For lower power applications, this PA
driver can be used to drive a 50Ω antenna directly.
R
N
E
W
D
TX VGA
Being essentially high impedance, TX IF IN responds
to the input voltage (rather than power), and amplifies
that voltage by the gain specified in the datasheet, then
presents the output voltage at a 50Ω impedance (after
upconversion). For characterization purposes, a 50Ω
shunt resistor is placed on the IF signal path, before
AC-coupling to the input. A 50Ω signal source is
applied directly across the shunt resistor, through a
coaxial test lead. The signal source sees the shunt
resistor and therefore a low SWR. Voltage gain is then
the same as power gain, simply the difference in dB
between the output power and the input power.
TX Upconverter
The IF to RF upconverter is a double-balanced differential mixer with a differential to single-ended converter on the output to supply 0dBm peak linear power
to the image filter. The upconverted SSB signal should
have -6dBm power at this point, and the image will
have the same power, but due to the correlated nature
of the signal and image, the output must support 0dBm
of linear power to maintain linearly.
E
S
TRANSMITTER
TX LPF and Mixers
The transmit section starts with a pair of 5-pole Bessel
filters identical to the filters in the receive section and
with the same 3dB frequency. These filters pre-shape
and band-limit the digital or analog input signals prior
to the first upconversion to IF. These filters have a high
input impedance and expect an input signal of
100mVPP typical. Following these low pass filters are
the I/Q quadrature upconverter mixers. Each of these
mixers is half the size and half the current of the RF to
IF downconverter on the RF2494. Recall that this
upconverted signal may drive the same SAW filter (in
half-duplex mode) as the RF2494 and therefore share
the same load. Having the sum of the two BB to IF mixers equal in size and DC current to the RF to IF mixer,
will minimize the time required to switch between RX
and TX, and will facilitate the best impedance match to
the filter.
N
O
T
FO
The AGC after the SAW filter starts with a switch and a
constant gain amplifier of 15dB, which is identical to
the circuitry on the receive IF AGC. This was done so
that the input impedance will remain constant for different gain control voltages. Following this 15dB gain
amplifier is a single stage of gain control offering 15dB
gain range. The main purpose of adding this variable
gain is to give the system the flexibility to use different
SAW filters and image filters with different insertion
loss values. This gain could also be adjusted real time,
if desired.
Rev A6 040930
11-249
RF2948B
IL = 1-3 dB
2.4 to 2.483 GHz
RF Micro Devices
2.4 GHz ISM Chipset
RX VGC
RF2948B
RF2494
SSOP-16 EPP
Gain
Select
OUT Q
SAW
IL = 10 dB max
RX
RX
LNA
Dual Gain Modes
IF Amp
TX
OUT I
Filter
2.4 to 2.483 GHz
RF
VCO
Dual
Frequency
Synthesizer
IF
VCO
x2
IG
N
S
TX
T/R
Switch
RF3000
Base Band Amp.
Active Selectable LPF
(fC = 1 MHz to 40 MHz)
+45°
-45°
Filter
10 dBm
PA Driver
E
S
RF2189
Σ
I INPUT
Filter
Selectable LPF
Q INPUT
TX VGC
D
IL = 1-3 dB
2.4 to 2.483 GHz
N
O
T
FO
R
N
E
W
Figure 1. Entire Chipset Functional Block Diagram
11-250
Rev A6 040930
RF2948B
Evaluation Board Schematic
(Download Bill of Materials from www.rfmd.com.)
R43
10 Ω
VCC
C68
100 pF
VREF1 BUF
C65
10 nF
R42
10 kΩ
C58
22 nF
C57
22 nF
J2
Q OUT
RX VGC
32
C77
100 pF
J1
X/TX IF IN
R10*
0Ω
28
27
26
1
24
2
23
3
22
4
21
5
C76
100 pF
R61
220 Ω
TX VGC
J6
IF OUT
10
11
12
R28*
270 kΩ
VCC
R62
51 Ω
C70
100 pF
2
VCC
P1-3
3
TX VGC
J10
PA OUT
CON3
P3
1
P3-1
P2-3
C20
10 nF
P2-4
RX/TX EN
3
PD
RX VGC
4
CON4
L16
3.9 nH
*Configured for RX Demod and
TX Cascaded Evaluation
Evaluate
Populate
TX Mod Out
R11
R62
N/A
TX Upconverter
R10
R9, R61
R56 to 0
R48
10 Ω
VCC
C54
22 pF
R45
47 Ω
R54
10 Ω
VCC
L14
33 nH
C43
1 nF
R39
2.2 kΩ
L15
27 nH
C44
12 pF
C50
3 pF
FL2
374 MHz
GND
J8
RF LO
L12
33 nH
50 Ω µstrip
R5
0Ω
OUT
GND
IN
R6*
0Ω
50 Ω µstrip
Unpopulate Changes
J9
PA IN
J7
RF OUT
N
O
T
FO
R
C19
100 pF
16
50 Ω µstrip
R7
0Ω
R8*
0Ω
GND
2
C95
22 pF
N
E
C12
10 nF
C40
22 pF
50 Ω µstrip
VREF1 BUF
GND
2
CON2
P2-2
15
D
P1-2
W
GND
P2
1
14
VCC
P1
C82
100 pF
13
C60
10 nF
50 Ω µstrip
1
C91
5 pF
C90
5 pF
C40
22 pF
R27
10 Ω
VCC
C24
10 nF
J5
TXI DATA
17
9
C69
10 nF
R32
47 Ω
R11*
0Ω
C48
1 nF
18
8
50 Ω µstrip
J11
IF LO
R9
0Ω
C47
1 nF
E
S
R56
130 Ω
J4
TXQ DATA
19
7
C74
10 nF
VCC C52
10 nF
20
6
VCC
J3
I OUT
25
IN
VCC
R1
51 Ω
RX/TX EN
R44
23.7k, 1%
29
OUT
C73
100 pF
R49
10 Ω
30
IG
N
S
PD
C72
10 nF
31
Rev A6 040930
11-251
RF2948B
Evaluation Board Layout
Board Size 2.2” x 2.1”
N
O
T
FO
R
N
E
W
D
E
S
IG
N
S
Board Thickness 0.031”, Board Material FR-4, Multi-Layer
11-252
Rev A6 040930
RF2948B
RX Voltage Gain versus VGC and VCC (Temp=25oC; RX IF
75.00
RX Gain versus IF LO Amplitude and Temp (VCC=3V; RX
IN=375MHz; I and Q out ∼ 300mVP-P IF LO=748MHz @ -10dBm)
70.00
Gain, 2.7V
65.00
Gain, 3V
60.00
Gain, 3.3V
VGC=1.6V; RX IF IN=375MHz, I and Q OUT~650mVP-P; IF LO=748MHz)
41.5
41.0
40.5
55.00
40.0
50.00
Gain (dB)
40.00
35.00
30.00
39.5
39.0
Gain, 85°C
20.00
38.0
15.00
37.5
10.00
5.00
37.0
0.00
-5.00
36.5
1.20
1.30
1.40
1.50
1.60
1.70
1.80
1.90
2.00
RX IQ Amplitude and Phase Error versus IF LO Amplitude and Temp
Ampl. Err, 25°C
Ampl. Err, 85°C
Ampl. Err, -40°C
Phase Err, 25°C
Phase Err, 85°C
Phase Err, -40°C
0.8
W
0.5
N
E
2.5
0.1
1250.0
2
1150.0
R
1100.0
1050.0
1000.0
950.0
900.0
850.0
1.5
800.0
1
750.0
700.0
0.5
650.0
600.0
0
-5.0
0.0
1.2
5.0
FO
-10.0
MHz; IF LO = 748 MHz at -10 dBm)
1200.0
3
-15.0
1.3
1.4
1.5
LO Amplitude (dBm)
1.6
1.7
1.8
1.9
2.0
RX VGC (VDC)
RX 3dB BW versus RBW (Temp=Ambient, VCC=3.15V, VGC=1.6V,
TX 3dB BW Point versus RBW (Broadband 50Ω match on IFOUT, Temp=Ambient,
VCC=3.15V, GCTX=1.5V, I&Qin=100mVP-P, IFLO=560MHz@-10dBm)
RX IFIN =-67dBm, IF LO=560MHz@-10dBm)
50.0
45.0
N
O
T
30.0
5.0
1300.0
4
VOUT (mVP-P)
0.6
-20.0
0.0
1400.0
3.5
-25.0
-5.0
1350.0
4.5
0.7
-30.0
-10.0
D
0.9
0.0
-15.0
RX OP1dB versus VGC and Temp (VCC = 3 V; RX IFIN = 375
5
0.2
-20.0
E
S
1.0
0.3
-25.0
LO Ampl. (dBm)
(VCC=3V; RX VGC=1.6V; RX IF IN=375MHz, I&Q OUT~650mVP-P; IF LO=748MHz)
0.4
Gain, -40°C
-30.0
RX VGC (VDC)
Amplitude Error (dB)
Gain, 25°C
38.5
25.00
IG
N
S
Gain (dB)
45.00
40.0
3dB BW Point [MHz]
3 dB BW Point [MHz]
25.0
20.0
15.0
10.0
35.0
30.0
25.0
20.0
15.0
10.0
5.0
5.0
0.0
0.0
1.0
10.0
100.0
RBW [kΩ]
Rev A6 040930
1000.0
1.0
10.0
100.0
1000.0
RBW [kΩ]
11-253
RF2948B
Modulator Amplitude Error and Image Suppression versus IF LO
Amplitude and Temp (VCC=3V; IF LO=748MHz; IQ IN=1MHz @ 100mVP-P)
1.0
28.0
54.0
27.5
48.0
27.0
0.7
42.0
26.5
0.6
36.0
0.5
30.0
0.4
24.0
0.3
18.0
24.5
0.2
12.0
24.0
0.1
6.0
23.5
0.0
23.0
Ampl.Err, 25°C
Ampl. Err, 85°C
Ampl. Err, -40°C
Image Supp, 25°C
Image Supp, 85°C
Image Supp, -40°C
LO Supp, 85°C
0.0
-30.0
-26.0
-22.0
-18.0
-14.0
-10.0
-6.0
-2.0
2.0
6.0
LO Supp, -40°C
26.0
25.5
25.0
-30.0
LO Amplitude (dBm)
-18.0
-14.0
-10.0
-6.0
-2.0
2.0
6.0
E
S
8.0
14.0
13.0
12.0
11.0
10.0
9.0
6.0
Gain, 2.7V
4.0
D
Gain, 3V
Gain, 3.3V
2.0
0.0
8.0
7.0
6.0
5.0
4.0
3.0
-2.0
-3.0
-4.0
-5.0
-6.0
0.4
0.6
0.8
1.0
1.2
1.4
1.6
-4.0
-6.0
-8.0
-10.0
-12.0
-14.0
-16.0
Gain, 25°C
-18.0
Gain, 85°C
-20.0
Gain, -40°C
-22.0
1.8
2.0
2.2
-26.0
2.4
FO
0.2
R
2.0
1.0
0.0
-1.0
Gain (dB)
W
-2.0
N
E
Gain (dB)
-22.0
Upconverter Voltage Gain versus RF LO Amplitude and Temp
(VCC=3V; TX VGC=1.6V; TX IF IN=374MHz@-35dBm, RF LO=2068MHz)
TX IF IN=374MHz @ -35dBm, RF LO=2068MHz @ -5dBm)
-22.0
-18.0
-14.0
-10.0
-6.0
-2.0
2.0
6.0
TX VGC (VDC)
LO Amplitude (dBm)
Upconverter Output P1dB versus RF LO Amplitude and Temp
(VCC=3V; TX VGC=1.6V; TX IF IN=374MHz, RF LO=2068MHz)
Upconverter Output P1dB versus VGC and VCC (Temp=25oC;
0.0
TX IF IN=374MHz, RF LO=2068MHz @ -5dBm)
-2.0
N
O
T
-2.0
-4.0
-6.0
-2.5
OP1dB, 2.7V
-3.0
OP1dB, 3V
-3.5
OP1dB, 3.3V
-4.0
-8.0
-4.5
-10.0
-5.0
OP1dB (dBm)
Gain (dB)
-26.0
LO Ampl (dBm)
Upconverter Voltage Gain versus VGC and VCC (Temp=25oC;
-12.0
-14.0
-16.0
-6.0
-6.5
-7.0
-8.0
-20.0
OP1dB, 25°C
-22.0
OP1dB, 85°C
-24.0
OP1dB, -40°C
-8.5
-9.0
-9.5
-26.0
-26.0
-5.5
-7.5
-18.0
-10.0
-22.0
-18.0
-14.0
-10.0
-6.0
LO Amplitude (dBm)
11-254
IG
N
S
0.8
LO Supp, 25°C
LO Supp (dBc)
0.9
Amplitude Error (dB)
Modulator LO Suppression versus IF LO Amplitude and Temp
(VCC=3V; IF LO=748MHz; IQ IN=1 MHz @ 100mVP-P)
60.0
-2.0
2.0
6.0
0.2
0.4
0.6
0.8
1.0
1.2
1.4
1.6
1.8
2.0
2.2
2.4
TX VGC (VDC)
Rev A6 040930
RF2948B
PA Output P1dB versus VCC and Temp
(PA IN=2442MHz @ -30dBm)
(PA IN=2442MHz)
15.0
14.5
14.0
13.5
13.0
OP1dB (dBm)
12.5
12.0
11.5
11.0
10.5
Gain, 25°C
10.0
Gain, 85°C
9.5
Gain, -40°C
9.0
2.7
3.0
IG
N
S
Gain (dB)
PA Gain versus VCC and Temp
10.1
10.0
9.9
9.8
9.7
9.6
9.5
9.4
9.3
9.2
9.1
9.0
8.9
8.8
8.7
8.6
8.5
8.4
8.3
8.2
8.1
8.0
2.7
3.3
3.0
OP1dB, 85°C
OP1dB, -40°C
3.3
VCC (VDC)
N
O
T
FO
R
N
E
W
D
E
S
VCC (VDC)
OP1dB, 25°C
Rev A6 040930
11-255
N
O
T
FO
R
N
E
W
D
E
S
IG
N
S
RF2948B
11-256
Rev A6 040930