ATMEL ATR2732N1-PBQW

Features
• ATR2732N1 is a Special Version of ATR2732 Recommended for Automotive
•
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Applications
Highly Integrated DAB Front-end Solution Covering Band III and L-band Reception
Convenient Internal Clock Generation, Single Reference Clock
Fractional PLL for VHF
Fully Integrated VCOs
High-precision Digitally Tunable Reference Oscillator
Integrated High-performance LNAs
Very Flexible Programming of the AGC
Automatically Aligned External Filter Tuning
Simple Three-wire Digital Control Interface for Easy Handling
Single Low Voltage (3.3V) Supply Operation
Low Current Consumption Due to Several Power-down Options
Small SMD Package (QFN 9 mm × 9 mm)
Applications
• Commercial DAB Receivers
• DAB Receiver Solutions for Car Radio Applications
• Portable DAB Solutions
Integrated DAB
One-chip Front
End
ATR2732N1
Summary
1. Description
The ATR2732N1 is a front-end monolithic integrated circuit, manufactured using
Atmel®’s silicon-germanium BiCMOS process (SiGMOS).
The ATR2732N1 carries out all functions of RF and IF processing, as well as the
clock-signal generation for these functions. Therefore, there is an integrated fractional
PLL, which, equivalent to most of the other functions, can be controlled via an external
digital bus. The RF functions include LNA, down-conversion mixing, amplifying, detection, and gain control. An external SAW filter is required in the signal path after the RF
functions. Additional amplifiers with detection and control functions are integrated IF
functions.
The device offers several tuning support functions, and was created to simplify the
design and manufacturing process. To this end, the number of external components
are minimal.
The part fits perfectly to Atmel’s DAB baseband processor ATR2740.
NOTE: This is a summary document.
The complete document is available
under NDA. For more information,
please contact your local Atmel sales
office.
9130AS–DAB–04/08
Figure 1-1.
Block Diagram
Gain
cntl
A
D
RSSI
PWR
cntl
Vtune
gen.
Control unit
VCO
L-band
PLL
VCO
VHF
frac. PLL
SPI interface
2. Pin Configuration
Pinning QFN64
MILINMILIN+
GDMIXL
PDFOUTL
VDD
XTALB
XTALA
VDI
XOUT
MISO
SCK
NSS
MOSI
SWITCHEN
WAGC
VA2
Figure 2-1.
64 63 62 61 60 59 58 57 56 55 54 53 52 51 50 49
48
1
47
2
46
3
45
4
44
5
43
6
42
7
41
8
QFN64
40
9
39
10
38
11
37
12
36
13
35
14
34
15
33
16
17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32
IFAGCINIF2OIF2O+
IFAGCIN+
AGCIF
IF2INIF2IN+
PDFOUTV
TNKREFO
TNKREFI
VTNKREF
VFIL1
VFIL2
VFIL3
GDVCOV
TUNVV
LNAVO+
LNAVOVABIAS
CVREF
IF1O+
IF1OVA1
RREFE
AGCSAW
IF1IN+
IF1INMIXVIN+
MIXVINMIXVO+
MIXVOVAVCOV
VAMIXL
VAVCOL
TUNVL
GDVCOL
LNAVIN+
LNAVL+
LNAVLLNAVINVALNA
LNALO+
LNALOAGCRF
GNDLNA
LNALIN+
LNALINIPINDIO
2
ATR2732N1
9130AS–DAB–04/08
ATR2732N1
Table 2-1.
Pin Description
Pin
Symbol
Function
1
VAMIXL
Supply voltage (mixer for L-band)
2
VAVCOL
Supply voltage (VCO for L-band)
3
TUNVL
4
GDVCOL
Ground (L-band VCO)
5
LNAVIN+
Input for VHF LNVGA (differential with pin 8)
6
LNAVL+
Connection for degeneration coil (inductance) to GNDLNA for VHF LNVGA
7
LNAVL–
Connection for degeneration coil (inductance) to GNDLNA for VHF LNVGA
8
LNAVIN–
Input for VHF LNVGA (differential with pin 5)
9
VALNA
10
LNALO+
(Differential) output for L-band LNVGA
11
LNALO–
(Differential) output for L-band LNVGA
Tuning voltage for integrated L-band VCO (connected to PLL loop filter)
Supply voltage for LNVGAs
12
AGCRF
13
GNDLNA
Ground for LNVGAs
Connection for time-constant capacitor of RF AGC (LNVGAs, external PIN diode)
14
LNALIN+
(Differential) input for L-band LNVGA
15
LNALIN–
(Differential) input for L-band LNVGA
16
IPINDIO
Current output to external PIN diode for additional attenuation of incoming signal (optional)
17
LNAVO+
(Differential) output of VHF LNVGA and/or mixer for L-band
18
LNAVO–
(Differential) output of VHF LNVGA and/or mixer for L-band
19
VABIAS
Supply voltage for (internal) voltage and current bias reference circuits
20
CVREF
Connection for capacitor for filtering internal voltage/current reference circuits (capacitor to VABIAS)
21
IF1O+
(Differential) Output of IFVGA1
22
IF1O–
(Differential) Output of IFVGA1
23
VA1
24
RREFE
25
AGCSAW
26
IF1IN+
(Differential) Input of 1st IFVGA
27
IF1IN–
(Differential) Input of 1st IFVGA
28
MIXVIN+
(Differential) Input of VHF mixer
29
MIXVIN–
(Differential) Input of VHF mixer
30
MIXVO+
(Differential) Output of VHF mixer
31
MIXVO–
(Differential) Output of VHF mixer
32
VAVCOV
Supply voltage (VHF VCO)
33
TUNVV
Tuning voltage for integrated VHF VCO (connected to PLL loop filter)
34
GDVCOV
35
VFIL3
Voltage outputs for frequency tuning of VHF filters: antenna filter, preselection filter
36
VFIL2
Voltage outputs for frequency tuning of VHF filters: antenna filter, preselection filter
37
VFIL1
Voltage outputs for frequency tuning of VHF filters: antenna filter, preselection filter
38
VTNKREF
Output voltage for tuning the reference tank (-varactor)
39
TNKREFI
Reference-tank connection for to generate the tuning voltages for the external VHF filters (varactors)
40
TNKREFO Reference-tank connection for to generate the tuning voltages for the external VHF filters (varactors)
41
PFDOUTV Output-of-phase comparator for VHF VCO (connected to PLL loop filter)
Supply voltage
Connection for current reference resistor (resistor to ground)
Connection for AGC time-constant capacitor of the VHF mixer
Ground (VHF VCO)
3
9130AS–DAB–04/08
Table 2-1.
4
Pin Description (Continued)
Pin
Symbol
Function
42
IF2IN+
(Differential) Input of 2nd IFVGA
43
IF2IN–
(Differential) Input of 2nd IFVGA
44
AGCIF
Connection for time-constant capacitor of IFVGAs’ AGC
45
IFAGCIN+
46
IF2O+
(Differential) Output of 2nd IFVGA
(Differential) Output of 2nd IFVGA
Input of IFAGC detector (differential with pin 48)
47
IF2O–
48
IFAGCIN–
49
VA2
50
WAGC
Window AGC input: All AGCs frozen and currents to capacitors switched off (necessary during Null Symbol
or when unused symbols are left out and the part is powered down using the SWITCHEN input)
51
SWITCHEN
Input for selection between the two enable registers, allowing a fast change between reduced, low-current,
and normal-reception mode, and offering current-saving capability
52
MOSI
Input of SPI bus (data, refer to SPI bus protocol)
53
NSS
Input of SPI bus (chip select, refer to SPI bus protocol)
54
SCK
Input of SPI bus (clock, refer to SPI bus protocol)
55
MISO
Output of SPI bus (data, refer to SPI bus protocol)
56
XOUT
Crystal oscillator clock output to baseband
If used: AC-couple to baseband (single VCXO concept)
If not used: short-circuit to GND
57
VDI
58
XTALA
Connection for reference clock crystal
59
XTALB
Connection for reference clock crystal
Input of IFAGC detector (differential with pin 45)
Supply voltage
Supply voltage from baseband (1.65V to 3.6V) to adaptation interface to baseband
60
VDD
61
PFDOUTL
Supply for digital circuits
62
GDMIXL
Ground (L-band mixer)
63
MILIN+
(Differential) Input of L-band mixer
64
MILIN–
(Differential) Input of L-band mixer
Paddle
GND
Output of phase comparator for VCO for L-band (connected to PLL loop filter)
Ground
ATR2732N1
9130AS–DAB–04/08
ATR2732N1
3. Functional Description
The ATR2732N1 front-end IC was developed as a tuner IC for DAB reception. It was designed
for operation in L-band (1452 MHz to 1492 MHz) and VHF BIII (167 MHz to 240 MHz). The front
end contains gain-controlled LNAs, an L-band mixer with a corresponding PLL, and a VHF-band
mixer with a fractional PLL. The IF path contains three gain-controlled amplifiers. The front-end
IC allows the use of automatic tuning, which contains an adjustable input filter for VHF BIII and
an adjustable preselection filter for L-band and VHF reception.
The high dynamic range of the RF inputs, the use of gain-controlled amplifiers and gain-controlled mixers in the RF and IF path, and an integrated driver for an external PIN diode
attenuator (VHF band) offer the possibility of handling even strong RF input signals.
The RF and IF parts include AGC functional blocks, which are needed for proper operation. The
thresholds are programmable via a simple serial bus.
The SPI bus is used to adjust and control all functional blocks.
The following sections briefly describe the major functions and features.
3.1
Main Functions
The following description gives a short overview of the general signal flow using the ATR2732N1
front-end IC for reception of DAB signals. Numbers in the text refer to the numbers in Figure 3-1
on page 6.
A DAB signal in the L-band frequency range (1452 MHz to 1492 MHz) is received by the L-band
antenna; a separate LNA with a separate input is available for the VHF Band III signals. In both
cases, the signal is band-pass filtered using a filter with low insertion loss. The internal variable
gain LNA (for L-band (1), for Band III (3)) amplifies the signal. For the L-band reception, a second band-pass filter is placed between the LNA output and mixer input at (2). This mixer
converts the L-band signal to the VHF BIII frequency range (167 MHz to 240 MHz). The signal
leaves the IC at point (4), followed by an external preselection filter.
This filter has an automatic tuner adjustment; that is, the tuning-voltage-generation block adjusts
the pass band of this filter to the desired frequency. After passing this filter, the RF signal is
down-mixed to a fixed IF frequency of 38.912 MHz. The IF signal is amplified and passed to a
SAW filter (5). The first IF variable-gain amplifier is followed by an IF filter at position (6). This filter is used as an anti-alias-filter. Finally, the DAB signal is amplified using the 2nd IF amplifier.
The signal leaves the front-end IC at (7), giving the signal to the DAB baseband IC.
5
9130AS–DAB–04/08
Figure 3-1.
Functional Block Diagram with Labelled Inputs and Outputs
4)
5)
6)
3)
7)
Gain
cntl
1)
2)
A
D
RSSI
PWR
cntl
Vtune
gen.
Control unit
3.2
VCO
L-band
PLL
VCO
VHF
frac. PLL
SPI interface
AGC in General
There are three AGCs in the ATR2732N1, one for the RF signals (around the LNAs) (1) and (3),
one for the very beginning of the IF path (mainly VHF mixer), and one for the IF amplifiers (5)
down to the output to baseband (7).
In these AGCs, the output signals of the relevant blocks are amplified, weakly band-pass filtered, rectified, and, finally, low-pass filtered. The voltage derived in this power-measurement
process is compared to a voltage threshold which can be digitally controlled by several bits,
independently of each other. The setting is done via the control bus. Depending on the result of
this comparison, charge pumps feed a positive or negative current in order to charge or discharge external capacitors. The voltage of these external capacitors is used to control the gains
of practically all blocks in the signal path.
By means of the control bus, the current of the AGC charge pump can be selected as specified
in the following table:
Table 3-1.
Selection of Time Constant Factor
MSB
LSB
Time Constant Factor
0
0
0
Infinite
0
0
1
32
0
1
0
16
0
1
1
8
1
0
0
4
1
0
1
2
1
1
0
1
1
1
1
0.2
The input pin WAGC, set to logical 1, always sets all AGCs to time constant Infinite (meaning
there is practically no current to the AGC capacitors), regardless of the actual status of the bus
settings.
6
ATR2732N1
9130AS–DAB–04/08
ATR2732N1
3.3
Device Support Functions
The ATR2732N1 has incorporated some very useful additional functions for handling the device
and optimizing the performance. First of all, a very precise clocking engine is incorporated. To
optimize the performance of this front end, a tuning support for alignment of the filters is featured
by this part too, similar to Atmel’s other radio front ends.
3.4
Tuning Support Functions
The ATR2732N1 includes three operational amplifiers, and three programmable digital-analog
converters (DACs). These outputs are used for automatic filter alignment of the tunable VHF
antenna filter and the preselection filter. DACs are incorporated in the ATR2732N1 for this tuning-support function.
For more details about the usage of the filter-tuning function contact your local Atmel sales office
and ask for the application note covering this feature.
3.5
DAC Usage
There are two DAC modes: pure DAC and Loop/Offset mode. In the pure DAC mode the DAC
sets a definite value. In the Loop/Offset mode the filter tuning voltage is derived from a reference
tank circuit (inductor plus varicap). An offset value can be added to this voltage. This Loop/Offset mode is the most useful mode and recommended for most applications. Temperature
compensation is also included in this mode.
3.6
RSSI Measurement
The ATR2732N1 offers the option of getting information about the field strength. This is not an
absolute real-field-strength value, but an indication of in which range the field strength is available. This information can be obtained from the 8 low bits of the status register.
3.7
Clocking Engine in General
The ATR2732N1 incorporates a convenient and flexible clocking engine. This includes VCOs
and PLLs for both bands, as well as a reference oscillator which can be precisely tuned using
the SPI interface. Together, this results in low external component count, but offers high flexibility and convenience.
3.8
PLL Part
The two PLL parts, the L-band PLL and the Band III PLL, perform phase lock of the LO signal to
an on-chip crystal reference oscillator. The Band III PLL incorporates a fractional part. This technique allows operation with an increased bandwidth of the PLL, which results in improved phase
noise.
7
9130AS–DAB–04/08
3.9
Fast Fractional PLL
The frequency of the VHF VCO is locked to a reference frequency by an on-chip fractional-N
PLL circuit which guarantees superior phase-noise performance. The reference frequencies for
the two PLL blocks are generated by an on-chip oscillator.
The VCOs are fully integrated, which simplifies the design of the device and reduces the bill of
materials of the application.
The LO signal for the first L-band mixer is derived from a PLL-controlled on-chip VCO. The
down-converting to an IF frequency of 38.912 MHz for VHF or converted L-band signal is done
by an additional on-chip VCO using an internal fractional-N PLL.
Due to the digital tuning option of the reference frequency, the ATR2732N1 is able to support the
single reference clock design if the baseband can support such a feature (as the ATR2740
does).
3.10
Reference Oscillator
An on-chip crystal oscillator generates the reference signal which is fed to the reference divider.
By applying a crystal to the pins XTALA and XTALB, this oscillator generates a highly stable reference signal.
Furthermore, the frequency of this reference oscillator can be digitally tuned via the SPI bus bits
XOTi (i = 11, ..., 0) with a 12-bit step size.
3.11
Reference Divider
Starting from a minimum value, the scaling factor of the 6-bit reference divider is arbitrarily
programmable by means of the SPI bus bits Ri (i = 5, ..., 0).
The output of this first programmable divider typically provides a 2.048 MHz reference frequency
for the L-band PLL.
A second programmable divider (dividing by 8 to 128) then outputs 64 kHz, which is a useful reference frequency for the VHF PLL.
Together with the fractional-N PLL, a step size of 16 kHz for the frequency setting of the VHF LO
is ensured.
3.12
Main Divider
The main divider consists of a fully programmable 13-bit divider which defines a division ratio N.
The applied division ratio is either N or N + 1, as specified by a special control unit. On average,
the scaling factors SF = N + k / 4 can be selected where k = 0, 1, 2, or 3.
3.13
Phase Comparator and Charge Pump
The tri-state phase detectors cause the charge pumps to source or sink currents at the output
pins PFDOUTV (for VHF) and PFDOUTL (for L-band) depending on the phase relation of its
input signals, which are provided by the reference and the main dividers, respectively.
8
ATR2732N1
9130AS–DAB–04/08
ATR2732N1
3.14
SPI Bus
The bus interface can be adapted to the signal voltage as a result of the supply voltage of the
external baseband processing unit connected to the bus. This is done with the help of a sensing
pin, VDI, which checks the supply voltage of the processor. The interface adapts itself to any
voltage between 1.65V and 3.5V.
3.14.1
Programming via SPI
Some things need to be taken into account when programming the ATR2732N1 via the SPI
interface: the data packet needs to be properly configured to write into the 14 different registers.
There are 16 registers. Fourteen of them are used to control the ATR2732N1. The two others,
registers 15 and 16, are Test Mode Registers. All these registers need to be reset by writing “0”
to every bit of each register one time, before starting the configuration of the ATR2732N1.
There are 4 address bits (bit 12 is address bit 0; bit 15 is address bit 3) which are used to select
the correct register. These are followed by 12 data bits (LSB is bit 0; MSB is bit 11). There is a
definite transmit order which needs to be considered: the MSB must be transmitted first (bit 15,
address bit 3), and LSB (data bit 0) last.
Unused and test mode register bits may not be documented in the datasheet and have to be set
to “0” in customer applications. Information about the status of the device is available by reading
one word (16 bits) out of the part.
Figure 3-2.
Timing Diagram of the SPI Interface (16 Bits per Transfer)
SCK
NSS
MOSI
MSB
LSB
MISO
MSB
LSB
A3
A2
A1
A0
D11
D10
D9
Adress
D8
D7
D6
D5
D4
D3
D2
D1
*
D0
Data
t per
tsud
t hda
t ch
t cl
t cet
tcet: Clock enable time
tsud: Data setup time
thda: Hold time of MOSI
tper: Clock period
tch: Clock high time
Clock low time
tcl:
SCK
NSS
MOSI
Note:
It is absolutely necessary to set the NSS signal back to high after every SPI access.
9
9130AS–DAB–04/08
L
4. Absolute Maximum Ratings
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. This is a stress rating
only and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of this
specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability.
Parameters
Symbol
Value
Unit
VCC
4.0
V
Operating case temperature
Tc
–40 to +100
°C
Storage temperature
Tstg
–40 to +150
°C
Supply voltage
Maximum RF input power VHF
25
dBm
Maximum RF input power L-band
20
dBm
Symbol
Value
Unit
RthJC
15
K/W
Symbol
Value
Unit
Supply voltage
VCC
3.0 to 3.5
V
Ambient temperature
Tamb
–40 to +90
°C
Notes:
1. The part may not survive all maximums applied simultaneously!
5. Thermal Resistance
Parameters
Junction, case
6. Operating Range
Parameters
10
ATR2732N1
9130AS–DAB–04/08
ATR2732N1
7. Electrical Characteristics
Test conditions (if not otherwise specified): VCC = +3.3V, Tamb = +25°C, 50Ω input match
No.
1
Parameters
Test Conditions
Pin
Symbol
Min.
Typ.
Max.
Unit
Type*
Power Supply
1.1
Supply voltage of front
end ATR2732N1
VCC
3.0
3.5
V
A
1.2
Supply voltage of
baseband processor
VDi
1.65
VCC
V
A
1.3
Leakage current, all off
I leak
25
µA
A
2
3
Power Control
2.1
Power on/off delay
1
µs
C
2.2
Power off/on delay
5
ms
C
2.3
Supply current L-band
off
150
mA
A
2.4
Supply current L-band
185
mA
A
2.5
Power-off tuning
voltage generation
140
mA
B
2.6
Average current
consumption
80
mA
B
3
SPI Bus Interface
Reception only VHF
Tuning generation not
active
3.1
BUS voltage high
VBUSH
VDi – 0.36
VDi + 0.3
V
A
3.2
BUS voltage low
VBUSL
–0.3
0.25
V
A
3.3
Clock frequency
1 / tper
2
MHz
A
3.4
Clock high time (SCK)
3.5
3.6
tch
0.4 × tper
Clock low time (SCK)
tcl
0.4 × tper
Clock enable time
tcet
5
3.7
Data set-up time
tsud
0.4 × tper
3.8
Hold time MOSI
thda
0.4 × tper
4
µs
Reference Crystal Oscillator
4.1
Operating frequency
16
24.576
4.2
Tuning range
120
4.3
Reference clock output
Sine wave output
voltage
5
MHz
C
210
ppm
A
0.5
Vpp
A
VHF Fractional PLL
5.1
LO frequency
6
L-band PLL
6.1
LO frequency
7
32
200
290
MHz
A
1.26
1.27
GHz
A
38.91
50
MHz
D
56
100
Ω
D
IF Interface
7.1
IF frequency range
7.2
Output impedance
(differential)
30
46, 47
*) Type means: A = 100% tested, B = 100% correlation tested, C = Characterized on samples, D = Design parameter
11
9130AS–DAB–04/08
7. Electrical Characteristics (Continued)
Test conditions (if not otherwise specified): VCC = +3.3V, Tamb = +25°C, 50Ω input match
No.
Parameters
Test Conditions
7.3
Driving capability/
max. load capacitance
(differential)
IFAGCIN+, IFAGCIN–
(pins 45, 48) directly
connected to IF20+,
IF20–
8
VHF Band Operation
8.1
Frequency range
8.4
Sensitivity
8.5
Maximum input power
level
9
Pin
Symbol
46, 47
fRfin
Min.
Typ.
5.5
7
Unit
Type*
pF
D
MHz
C
–98
dBm
C
–5
dBm
C
MHz
C
–96
dBm
C
–15
dBm
C
167
8 dB SNR at IF output
to baseband, measured
with sample application
Max.
240
L-band Operation
9.1
Frequency range
9.4
Sensitivity
9.5
Maximum input power
level
fRfin
8 dB SNR at IF output
to baseband, measured
with sample application
1452
1492
*) Type means: A = 100% tested, B = 100% correlation tested, C = Characterized on samples, D = Design parameter
12
ATR2732N1
9130AS–DAB–04/08
ATR2732N1
8. Ordering Information
Extended Type Number
Package
Remarks
ATR2732N1-PBQW
QFN64
9 mm × 9 mm, 0.5 mm pitch, lead-free
ATR2732N1-PBPW
QFN64
9 mm × 9 mm, 0.5 mm pitch, lead-free
9. Package Information
Package: VQFN_ 9 x 9_64L
Exposed pad 5.8 x 5.8
Dimensions in mm
Bottom
Not indicated tolerances ±0.05
64
5.8±0.15
Top
49
64
1
48
1
16
33
16
Pin 1 identification
Z
9
32
17
0.5 nom.
0.2
7.5
Z 10:1
0.4±0.1
0.9±0.1
technical drawings
according to DIN
specifications
Drawing-No.: 6.543-5119.01-4
0.23±0.07
Issue: 1; 31.05.05
13
9130AS–DAB–04/08
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