ETC XE1218AS000BF

Datasheet XE1218A: Low
Power single die FM receiver
VCCR
RFT
RFI
RFG
VCCA
VDD
FM
DEMOD
LNA
LON
OUT
Audio
SW
AFC
OSC
LOP
VCCO
AUD
XP
XN
VM
PA
VSS
EAR
VOL
XE1218A
Low power single die FM receiver
General Description
Applications
The XE1218 is a single die, low power, FM
receiver operating in the VHF band from 130MHz
to 230MHz. Its highly integrated architecture allows
for RF and audio functions on the same die, whilst
minimizing the external components needed to
build a complete application at the same time.
The XE1218A enables single chip, complete audio
transmission solutions, where the antenna feeds
the incoming RF signal directly into the XE1218A
and an amplified audio signal can be fed to an
earphone directly from the XE1218A’s output.
Flexibility has been built into the XE1218A: various
different transmission channels can be selected,
the audio output can also be fed to a post
processing circuit such as sound de-emphasis or
an external power amplifier.
The XE1218A is optimized for battery powered
applications, it can be operated directly on one
lithium 1.5V battery cell.
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Wireless phone headset
Local area voice paging
FM broadcasting miniature receiver
Toys
Main features
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Tuneable from 130MHz to 230 MHz
High reception sensitivity: -100dBm
Integrated RF filtering
Low voltage operation: down to 1.1V
Low power consumption: typical 2.5mA
6 kHz audio bandwidth
40 dB audio SNR
Integrated earphone audio amplifier
Line out for external audio amplifier
Mute function
Ordering Information
Part Number
XE1218AS000BF
Temperature range
-10°C to 40°C
Cool Solutions for Wireless Connectivity
XEMICS SA • e-mail: [email protected] • web: www.xemics.com
Package
Bare die
Datasheet XE1218A: Low
Power single die FM receiver
Table of Contents
1. Functional description
1.1General description
1.2RF front end
1.3Audio stage
3
3
3
3
2. Functional implementation
2.1 Block diagram
2.2 Operation overview
2.3 Application example
4
4
5
4
3. Electrical characteristics
3.1 Absolute maximum ratings
3.2 Recommended operating conditions and electrical specifications
5
5
5
4. Interconnections
4.1 Bare die pad out
4.2 Pad coordinates
4.3 XE1218A packaging
4.4 TQFP44 pin-out
6
6
7
7
8
5. Input – output signal description
9
6. Application information
6.1 Recommended crystal oscillator
6.2 Using a low impedance audio output
6.3 Using the high impedance line out OUT
6.4 Recommended antenna
10
10
10
10
11
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Datasheet XE1218A: Low
Power single die FM receiver
1. Functional description
1.1
General description
The XE1218A is an integrated FM receiver including all the necessary functions to process a modulated RF
signal at its input and deliver a “speech quality” audio signal at its output. The XE1218A was designed for
maximum system simplicity thus it requires only 12 external components to offer antenna in, audio out
functionality. The XE1218A also offers design flexibility. A direct connection to an earphone is possible through
the pin EAR, this takes advantage of the internal audio power amplifier or an external audio amplifier, or an
audio processing device can be connected via the OUT (line out) pin.
1.2
RF front end
The FM signal received through the antenna is delivered to an integrated LNA via an external matching circuit.
A low IF architecture is implemented to down-convert the incoming signal to an intermediate frequency (IF) of
25kHz. This IF signal is then filtered to remove any DC components and equalized to offer a clean digital signal
to the demodulator. The FM demodulator uses digital delay line architecture to convert the signal to a pulse
width modulated signal at twice the IF frequency. The XE1218A has an integrated AFC which is used for the
demodulator to have its clock frequency track the IF frequency.
1.2.1 LNA
The noise figure (NF) for this block is less than 6dB, for an antenna impedance in the 1 to 2 kΩ range. Out of
the 6dB, 3dB is due to the noise of the image frequency that is not rejected. The sensitivity is –100dBm
(SINAD=10 dB, fdev = 3kHz).
1.2.2 Mixer, down-conversion
The down-conversion is implemented as a Gilbert cell. This implementation uses low IF and does not have
provisions for integrated image rejection. The incoming audio channel will be demodulated at Flo = FIN – 25kHz.
This is to say that the image frequency will be located at FIN – 50kHz and will not be attenuated by the
XE1218A’s RF receiving circuitry. For multi-channel operation within reception range of several XE1218A
receivers, it is recommended that the various carrier frequencies be spaced by at least 100kHz, better yet
200kHz.
1.2.3 DC offset cancellation, IF amplifier chain
DC components are attenuated in an off-set cancellation block. An on-chip low pass filter provides attenuation
greater than 65dBm measured FIF + 100kHz
1.2.4 Demodulation and AFC circuitry
The demodulator converts the signal from the IF amplifier into a pulse width modulated signal at twice the IF
frequency. A follow-on block generates the AFC to track the IF frequency. Proper tracking of the IF frequency is
necessary for the stability of the RF link as the XE1218A operates in narrow band mode.
1.2.5 Crystal and local oscillator
The local oscillator provides the XE1218A’s down-converter mixer with the proper frequency: Flo. It is
implemented with a crystal oscillator working on the external crystal’s overtone harmonic.
1.3
Audio stage
1.3.1 Audio processing
The XE1218A integrated audio processing circuitry filters the input pulse width modulated (PWM) signal from
the demodulator and provides for two different output feeds. All necessary bias currents and voltages for this
analog block are on-chip, including a voltage multiplier circuit. When the incoming RF signal becomes low, the
signal to noise ratio at the audio output decreases, which drastically reduces the sound quality and intelligibility.
For user convenience, a mute function is implemented in the audio section. When the signal to noise ratio at the
output is too low (typ. 10 to 15 dB) the audio output is shut down.
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Datasheet XE1218A: Low
Power single die FM receiver
1.3.2 Audio output stage
An integrated power amplifier (PA) allows for a direct connection to an earphone. Controlled by an external
potentiometer (100kΩ) a maximum attenuation of 10dB is achievable on the EAR output, 21.5dB with 1MΩ. A
high impedance line out (10kΩ) is available through the pad OUT.
2. Functional implementation
2.1 Block diagram
VCC
A1
C1
VCC
VCC
L1
VCCR
RFT
VCCA
VDD
VCCO
AUD
C4
RFI
FM
DEMOD
LNA
L4
C5
RFG
AFC
OSC
LOP
LON
OUT
Audio
SW
XP
VM
XN
L3
C3
L2
VSS
PA
XE1218
Line OUT
EAR
VOL
R1
Volume
Control
C2
Xtal
2.2 Operation overview
While the XE1218A is a single channel receiver, various fixed frequencies can be selected between 130MHz
and 230MHz. This is achieved by changing the external RF front-end components: L1, L2, L3, L4, C1, C2, C4,
C5 and Xtal. The XE1218A FM receiver connects to the antenna via a differential input: pins RFI and RFG. The
external components L4, C4 and C5 must tune the circuit to the incoming carrier frequency. L2 and C2 are
calculated to tune the oscillator to the desired incoming carrier frequency. Xtal is selected according to the
desired input carrier frequency, L3 relaxes the oscillator’s Q factor to insure greater reception stability.
Reception sensitivity is determined through the LNA’s external tank circuit: C1 and L1.
Two types of audio outputs can be selected: OUT (line out, 10kΩ output impedance) to connect to an external
audio processing circuit or amplifier and EAR for direct connection to an earphone. An external R1 is used to
adjust the volume through pin VOL. The internal RF and audio blocks each have their own supply voltage as
well as a common VDD. Clean voltage must be supplied to each of these supplies (VCCR, VCCA, VCCO and
VDD).
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Datasheet XE1218A: Low
Power single die FM receiver
2.3 Application example
To tune the above circuit to a carrier frequency of 160.325MHz, the following external components must be
implemented:
L1
56nH-5%
C1
12pF-5%
C5
L2
56nH-5%
C2
10pF- 15pF-5% R1
L3
180nH-5%
C3
10nF-5%
Xtal
L4
120nH – 5%
C4
22pF-5%
A1
The value of the capacitors given here may change slightly for different PCBs.
2pF - 6pF-5%
100kΩ - 10%
160.325MHz
Wire l > 40mm
3. Electrical characteristics
3.1 Absolute maximum ratings
Parameter
Supply voltage
Storage Temperature
Min
-0.3V
-55°C
Max
2.5V
+125°C
Stress beyond those listed under absolute maximum ratings may cause permanent damage to the XE1218
device. These are stress ratings only, and functional operation of the device at these or any other condition
beyond those under “recommended operating conditions” is not implied. Exposure to “absolute maximum
ratings” conditions for extended periods may affect the device reliability.
3.2 Recommended operating conditions and electrical specifications
General conditions: Temp = 25°C, VDD= 1.3V, Carrier Frequency=160MHz, unless otherwise specified
Symbol
Description
Condition
Min
Typ.
Max
Unit
1.1
1.3
2.5
1.6
4.5
V
mA
-10
+40
°C
130
230
8
MHz
kHz
±20
ppm
Electrical supply parameters
VDD
IDD
Power supply
Supply current
TEMP
RF-IN
F-DEV
Carrier frequency
Deviation frequency
LO-D
Local Oscillator shift
RFS
ACR
RF input sensitivity
Adjacent channel
rejection
AOB
Audio Output
bandwidth (typical)
Audio distortion on
PA output (EAR)
AOD
5
Receiver ON, without
earphone PA enabled
Operating temperature range
Radio Frequency parameters
Input range
Maximum deviation of the
incoming modulated signal
Crystal ageing and
temperature drift not
accounted for
fmodulated = 1kHz, fdev= 3kHz
funwanted = fRfin + 100kHz
fmodulated = 1kHz, fdev= 3kHz
Pin = RFS + 10dBm
SINAD = 10dB
Audio parameters
Fdev = 3kHz
Only relevant if using the
direct earphone connection
fmodulated= 1kHz, fdev = 5kHz
Rvol = 100kΩ
Pin = -60dBm, BW = 20kHz
-100
50
0.1
2
dBm
dB
6
kHz
8
%
D0204-157
Datasheet XE1218A: Low
Power single die FM receiver
Symbol
Description
ASN
Audio SNR on PA
output (EAR)
DC-EAR
DC voltage on EAR
output
Z-EAR
External earphone
impedance
Condition
Min
Audio parameters cont.
fmodulated= 1kHz, fdev = 3kHz
Rvol = 100kΩ
Pin = -60dBm, BW = 6kHz
Only in use for direct
earphone connection to the
PA (EAR)
Impedance of the earphone
that directly connects to the
EAR output
Typ.
Max
Unit
40
dB
150
450
mV
200
1000
Ω
4. Interconnections
The XE1218A is delivered in bare die. The complete FM receiver functionality requires 16 bond wire
connections from the die to the 1st level substrate (for EAR functionality, 18 wire bonds for the line out
connection). The die measures 21.8mm2 (4.9mm x 4.45mm). For prototyping purposes, the XE1218A is also
available in a TQFP44 package, see details on the next page.
4.1 Bare die pad out
4900 µm
AUD
LON
LOP
EAR
VDD
VCCA
VCCO
VSS
XN
XP
4450µm
RFT
VCCR
VOL
OUT
RFI
RFG
VM
Origin reference (0,0)
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Datasheet XE1218A: Low
Power single die FM receiver
4.2 Pad coordinates
The pad coordinates below are referenced to the lower left corner of the die (see picture above). The reference
is to the center of the bond pad.
Pad name
LON
LOP
XN
XP
RFT
VCCR
RFI
RFG
X,Y coordinates (µm)
145, 3569
145, 3391
145, 2843
145, 2664
145, 1944
145, 1765
145, 1283
145, 1105
Pad name
AUD
EAR
VDD
VCCA
VCCO
VSS
VOL
OUT
VM
X,Y coordinates (µm)
145, 4166
4629, 4141
4629, 3962
4629, 3782
4629, 3526
4629, 3270
4629, 2323
4629, 1809
4629, 757
4.3 XE1218A packaging
The following TQFP package is not currently qualified for production volumes. It serves solely prototyping
purposes.
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Datasheet XE1218A: Low
Power single die FM receiver
4.4 TQFP44 pin-out
Only the relevant signals are listed below. All other pins should remain N.C. (not connected)
Pin name
LON
LOP
XN
XP
RFT
VCCR
RFI
RFG
8
Pin number
4
3
6
5
7
8
10
11
Pin name
EAR
VDD
VCCA
VCCO
VSS
VOL
OUT
VM
AUD
Pin number
34
33
32
31
30
26
24
23
44
D0204-157
Datasheet XE1218A: Low
Power single die FM receiver
5. Input – output signal description
Pin Name
Description
Functionality
Type
LOP
Local oscillator tank
Analog I/O
LON
Local oscillator tank
XP
Crystal oscillator
connection
Crystal oscillator
connection
RF signal input
(differential to RFG)
RF signal ground
(differential to RFI)
LNA tank circuit
The integrated local oscillator is used to produce the
mixer frequency to down convert the incoming carrier
frequency. This local oscillator requires an external tank
circuit, which must be tuned to select the desired crystal
overtone.
The crystal is connected between pins XP and XN. An
inductance must be put in parallel.
XN
RFI
RFG
RFT
VCCR
Supply voltage to the
RF circuitry
VDD
Supply voltage to the
digital circuitry
VSS
Ground reference
VCCA
Supply voltage to the
analog circuitry
External capacitor for
voltage multiplier
VM
VCCO
VOL
Supply for audio
circuitry
Volume control
OUT
EAR
Line out
Earphone out
AUD
Audio out de-coupling
9
Analog I/O
Analog I/O
Analog I/O
The incoming carrier frequency is fed to the LNA via a
differential input (RFI and RFG). For best results, an
external capacitive impedance matching circuit is
required.
The LNA has an external tank circuit to optimize its gain.
The resonance frequency of this tank circuit must be
adjusted to be the same as the incoming carrier
frequency
This is the supply voltage for the RF section of the
XE1218A. It must be clean and de-coupled properly.
Analog Input
This is the supply voltage for the digital and control
circuitry of the XE1218A. It must be clean and decoupled properly.
This is the ground reference. VDD, VCCA and VCCR
are referenced to this pin.
This is the supply voltage for the analog section of the
XE1218A. It must be clean and de-coupled properly.
The XE1218A audio circuitry requires an internal
voltage multiplier. This multiplier requires and external
capacitor to be connected to VM
This pin must be connected to VDD
Digital supply
This is used when the integrated PA is in use. An
external potentiometer (100kΩ to 1MΩ) will allow
varying the volume at the EAR output. 100kΩ will give
you a tuning range of 0dB to –10dB and 1MΩ will
equate to 0dB to –21.5dB
High impedance audio output: impedance = 10kΩ
Earphone output, average 250mV, ±3dB, speaker
impedance must be between 200Ω and 1kΩ
This pin is only used when the line out (OUT) is
selected. An additional de-coupling capacitor is needed
for line out best performance
Analog input
Analog ground
Analog I/O
Analog supply
Digital ground
Analog supply
Analog I/O
Supply input
Analog output
Analog output
Analog output
D0204-157
Datasheet XE1218A: Low
Power single die FM receiver
6. Application information
6.1 Recommended crystal oscillator
The recommended characteristics of the crystal used for generating the local oscillator frequency (LO) are the
following:
-
Supplier: Telequarz
Type: HSLX5132
Frequency: 160.325 MHz (7th overtone)
Motional capacitance Cs = 0.2 fF ± 0.15 fF
Calibration tolerance at 25 °C: ± 10 ppm
Stability over temperature range: ± 5 ppm
Ageing in the first year: ± 3 ppm
6.2 Using a low impedance audio output
The XE1218A provides two possible audio outputs: a) direct connection to an earphone and b) a high
impedance line out (10kΩ). Should a low impedance output be required to interface with an audio post
processing stage, this output can be matched by using the EAR output of the XE1218A. The adaptation should
be as follows:
EAR
Low impedance line out
1kΩ
6.3 Using the high impedance line out OUT
If the line out OUT pin is used on the XE1218A to interface to an analog audio post processing circuit such as a
sound de-compounder or external power amplifier, a de-coupling capacitor must be connected to the pin AUD
of the XE1218A. Please note that this capacitor is only necessary when the system uses the OUT connection.
When the internal amplifier is used and an earphone is directly connected to the output EAR, the pin AUD must
not remain connected.
4.7nF-5%
AUD
OUT
10
High impedance line out (10kΩ)
D0204-157
Datasheet XE1218A: Low
Power single die FM receiver
6.4 Recommended antenna
All antenna types need to be adapted with regards to the selected operating frequency. In the examples below
the antennas are tuned for an incoming frequency of 160.350MHz (FO + FIF: 160.325MHz + 25kHz). The
antenna can be a printed wire on the PCB, or real estate permitting a wire or a coil.
In the case of a wire antenna, its length should be slightly above 40mm (Figure 1). It can either be printed
straight on the PCB or a loose wire can be used. A magnetic coil antenna however is recommended because
unlike a wire antenna, it is less sensitive to de-tuning by the proximity of the body.
The coil is made of 1.8 turns of a 0.4mm diameter copper wire. The diameter of the antenna is 14mm for a
typical coil inductance of 140nH (Figure 2). The coil is soldered in such a way as to be elevated from the PCB
by at least 10mm, this is to reduce losses due to the ground plane effect of the board.
The value of the capacitors given here may change slightly for different PCBs.
D = 14mm
L > 40mm
H > 10mm
22pF
3.9pF
RFI
120nH
2-10pF
RFI
2-10pF
RFG
Figure 1
RFG
Figure 2
XEMICS 2002
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