STMICROELECTRONICS STLC60134

STLC60134S

TOSCA INTEGRATED ADSL CMOS
ANALOG FRONT-END CIRCUIT
FULLY INTEGRATED AFE FOR ADSL
OVERALL 12 BIT RESOLUTION, 1.1MHz
SIGNAL BANDWIDTH
8.8MS/s ADC
8.8MS/s DAC
THD: -60dB @FULL SCALE
4-BIT DIGITAL INTERFACE TO/FROM THE
DMT MODEM
1V FULL SCALE INPUT
DIFFERENTIAL ANALOG I/O
ACCURATE CONTINUOUS-TIME CHANNEL
FILTERING
3rd & 4th ORDER TUNABLE CONTINUOUS
TIME LP FILTERS
0.5 WATT AT 3.3V
0.5µm HCMOS5 LA TECHNOLOGY
64 PIN TQFP PACKAGE
DESCRIPTION
STLC60134S is the Analog Front End of the
STMicroelectronics Tosca ADSL chipset and
when coupled with STLC60135 (DTM modem) alFigure 1. Block Diagram
R-MOS-C
TUNING
I/V-REF
TQFP64
ORDERING NUMBER: STLC60134S
lows to get a T1.413 Issue 2 compliant solution.
The STLC60134S analog front end handles 2
transmission channels on a balanced 2 wire interconnection; a 16 to 640Kbit/s upstream channel
and a 1.536 to 8.192Mbit/s downstream channel.
A 256 carrier DMT coding (frequency spacing
4.3125kHz) transforms the downstream channel
to a 1MHz bandwidth analog signal (tones 32255) and the upstream channel (tones 8-31) to a
100kHz bandwidth signal on the line.
This asymmetrical data transmission system uses
high resolution, high speed analog to digital and
digital to analog conversion and high order analog filtering to reduce the echo and noise in both
XTAL-DRIVER
VCXO
DAC
ADC
TXP
TXN
G=-15...0dB
step=1dB
- +
+
-
ERROR
CORRECTION
13 bits
ANALOG
LOOP
MUX
AGCtx
1.1MHz
HC2
G=0..31dB
step=1dB
HC1
DIGITAL
IF
138KHz
DIGITAL
LOOP
SC2
DAC
12 bits
MUX
4 bits
+
- +
RXP(0:1)
RXN(0:1)
1.1MHz
4 bits
AGCrx
D99TL453
August 1999
1/22
STLC60134S
the ATU-C/ATU-R receivers and transmitters. External low noise driver and input stage used with
STLC60134S guarantee low noise performances.
The STLC60134S chip can be used at ATU-C
and ATU-R ends (behaviour set by LTNT pin).
The selection consists mainly of a filter interchange between the RX and TX path. The filters
(with a programmable cutoff frequency) use automatic Continuous Time Tuning to avoid time varying phase characteristic which can be of dramatic
consequence for DMT modem. It requires few external components, uses a 3.3V supply (a separate 3.0V supply of the digital part is possible)
and is packaged in a 64-pin TQFP in order to reduce PCB area.
The Receiver (RX) part
The DMT signal coming from the line to the
STLC60134S is first filtered by the two following
external filters:
POTS HP filter: Attenuation of speech and POTS
signalling
Channel filter: Attenuation of echo signal to
improve RX dynamic
An analog multiplexer allows the selection between two input ports which can be used to select
an attenuated(0, 10dB for ex.) version of the signal in case of short loop or large echo. The signal is amplified by a low noise gain stage (031dB) then low-pass filtered to avoid anti-aliasing
and to ease further digital processing by removing unwanted high frequency out-of-band noise.
A 12-bit A/D converter samples the data at
8.832MS/s (or 4.416MS/s in alternative mode),
transforms the signal into a digital representation
and sends it to the DMT signal processor via the
digital interface.
The Transmitter (TX) part
The 12-bit data words at 8.832MS/s (or
4.416MS/s) coming from the DMT signal processor through the digital interface are transformed
by D/A converter into a analog signal.
This signal is then filtered to decrease DMT sidelobes level and meet the ANSI transmitter spectral response but also to reduce the out-of-band
noise (which can be echoed to the RX path) to an
acceptable level. The pre-driver buffers the signal
for the external line driver and in case of short
loop provide attenuation (-15...0dB).
The VCXO part
The VCXO is divided in a XTAL driver and a auxiliary 8 bits DAC for timing recovery.
The XTAL driver is able to operate at 35.328MHz
and provides an amplitude regulation mechanism
to avoid temperature / supply / technology de2/22
pendent frequency pulling.
The DAC which is driven by the CTRLIN pin provides a current output with 8-bit resolution and
can be used to tune the XTAL frequency with the
help of external components. A time constant between DAC input and VCXO output can be introduced (via the CTLIN interface) and programmed
with the help of an external capacitor (on VCOC
pin).
See chapter ’VCXO’ for the external circuit related to the VCXO.
The Digital Interface part
The digital part of the STLC60134S can be divided in 3 sections:
The data interface converts the multiplexed
data from/to the DMT signal processor into
valid representation for the TX DAC and RX
ADC. It performs also the error correction
mechanism needed at the (redundant) ADC
output.
The control interface allows the board processor to configure the STLC60134S paths
(RX/TX gains, filter band, ...) or settings (OSR,
vcodac enable, digital / analog loopback,...).
The test interface to enable digital (Full Scan,
nandtree, loop backs, functional,...) or analog
(TIN, TOUT assignation) tests to be performed.
DMT Signal
A DMT signal is basically the sum of N independently QAM modulated signals, each carried
over a distinct carrier. The frequency separation
of each carrier is 4.3125kHz with a total number
of 256 carriers (ANSI). For N large, the signal can
be modelled by a gaussian process with a certain
amplitude probability density function. Since the
maximum amplitude is expected to arise very
rarely, we decide to clip the signal and to tradeoff the resulting SNR loss against AD/DA dynamic. A clipping factor (Vpeak/Vrms = ”crest factor”) of 5 will be used resulting in a maximum
SNR of 75dB.
ADSL DMT signals are nominally sent at -40dBm/Hz
±3dB (-3.65dBm/carrier) with a maximal power of
100mW for down link transmitter and 15.7mW for
uplink transmitter.
DMT symbols are transmitted without ’windowing’ causing sin (x)/x like sidelobes. For spectral
response shaping, the 1st sidelobe level is assumed to be 13dB under the carrier level with
an attenuation of -20dB/dec.
The minimum SNR + D neede d for DMT carrier
demodulation is about (3 ⋅ N + 20) dB with a
minimum of 38dB were N is the constellation size
of a carrier (in bits).
STLC60134S
mit power and line impedance signal amplitudes
can differ from these values.
The reference line impedance for all power calculations is 100Ω.
Maximum / minimum signal levels
The following table gives the transmitted and received signal levels for both ATU-R and ATU-C
sides. All the levels are referred to the line voltages (i.e. after hybrid and transformers in TX direction, before hybrid and transformer in RX direction).
Note that signal amplitudes shown below are for
illustration purpose and depending on the trans-
PACKAGE
The STLC60134S is packaged in a 64-pin TQFP
package (body size 10x10mm, pitch 0.5mm).
Table 1. Target Signal Levels (on the line).
Parameter
ATU - C
ATU - R
RX
TX
RX
TX
Max level
839 mVpdif
15.8 Vpdif
3.95 Vpdif
3.4 Vpdif
Max RMS level
168 mVrms
3.16 Vrms
791 mVrms
671 mVrms
Min level
54 mVpdif
3.95 Vpdif
42 mVpdif
839 mVpdif
Min RMS level
11 mVrms
791 mVrms
8 mVrms
168 mVrms
Table 2. Total Signal Level (on the line).
Parameter
ATU - C
ATU - R
RX
Max level for receiver
TX
RX
4 Vpdif (Long line)
TX
4.2 Vpdif (Short line)
RXIN1
RXIP1
AVSS6
AVSS2
IREF
AVDD2
IVCO
VCXO
RES
AVDD1
XTALI
XTALO
AVSS1
DVSS2
TX3
TX2
Figure 2. Pin Connection
64 63 62 61 60 59 58 57 56 55 54 53 52 51 50 49
TX1
1
48
RXIP0
TX0
2
47
RXIN0
NU3
3
46
GC1
NU2
4
45
GC0
NU1
5
44
VCOC
NU0
6
43
GP2
CTRLIN
7
42
AVDD6
DVSS1
8
41
AVDD5
CLKM
9
40
RES
CLNIB
10
39
RES
CLWD
11
38
AGND
RX3
12
37
RES
RX2
13
36
RES
RX1
14
35
AVSS5
RX0
15
34
AVSS4
DVDD1
16
33
GP1
TXP
TXN
NC1
NC0
AVDD4
AVDD3
VREF
VRAN
VRAP
GP0
AVSS3
RES
LTNT
RESETN
DVDD2
PDOWN
17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32
D98TL355mod
3/22
STLC60134S
Table 3. Pin Functions.
N.
Name
Function
PCB connection
Supply
ANALOG INTERFACE
24
25
26
31
32
38
44
45
46
47
48
49
50
53
55
56
59
60
VRAP
VREF
VRAN
TXP
TXN
AGND
VCOC
GC0
GC1
RXN0
RXP0
RXN1
RXP1
IREF
IVCO
VCXO
XTALI
XTALO
positive voltage reference ADC
ground reference ADC
negative voltage reference ADC
pre driver output
pre driver output
virtual analog ground (AVDD/2 = 1.65V)
VCODAC time constant capacitor
External gain control output LSB
External gain control output MSB
analog receive negative input Gain 0
analog receive positive input Gain 0
analog receive negative input Gain 1 (most sensitive input)
analog receive positive input Gain 1 (most sensitive input)
current reference TX DAC/DACE
current reference VCO DAC
VXCO control current
XTAL oscillator input pin
XTAL oscillator output pin
Decoupling network
Decoupling network
Decoupling network
Line driver input
Line driver input
Decoupling network
VCODAC cap.
AVDD3
AVDD3
AVDD3
AVDD4
AVDD4
AVDD5
AVDD5
AVDD5
AVDD5
Echo filter output
AVDD5
Echo filter output
AVDD5
Echo filter output
AVDD5
Echo filter output
AVDD5
Decoupling network AVDD2
VCO bias network AVDD1
VCXO filter
AVDD1
Crystal + varicap
AVDD1
Crystal + varicap
AVDD1
DIGITAL INTERFACE
1
2
7
9
10
11
12
13
14
15
18
19
TX1
TX0
CTRLIN
CLKM
CLNIB
CLWD
RX3
RX2
RX1
RX0
PDOWN
LTNT
20
22
33
43
63
64
21
RESETN
GP0
GP1
GP2
TX3
TX2
RES
36,
37, 39,
40, 57
RES
digital transmit input, parallel data
digital transmit input, parallel data
serial data input (settings)
Async Interface
master clock output, f = 35.328MHz
Load = CL<30pF
nibble clock output, f = 17.664MHz (OSR = 2) or ground (OSR = 4) Load = CL<30pF
word clock output, f = 8.832/4.416MHz
Load = CL<30pF
digital receive output, parallel data
Load = CL<30pF
digital receive output, parallel data
Load = CL<30pF
digital receive output, parallel data
Load = CL<30pF
digital receive output, parallel data
Load = CL<30pF
power down select, ”1” = power down
Power down input
ATU-R / ATU-C select pin 1, ATU-R = 0 /ATU-C = 1 / test
VDD in ATU-C mode
mode MSB
reset pin (active low)
RC- reset
General purpose output 0 (on AVDD 1)
Echo filter output
General purpose output 1 (on AVDD 1)
Echo filter output
General purpose output 2 (on AVDD 1)
Echo filter output
digital transmit input, parallel data
Load = CL<30pF
digital transmit input, parallel data
Load = CL<30pF
RESERVED
Must be connected
to DVSS (input)
Must be connected
RESERVED
to AVSS (input)
SUPPLY VOLTAGES
8
16
17
23
27
4/22
DVSS1
DVDD1
DVDD2
AVSS3
AVDD3
Digital I/O supply voltage
digital internal supply voltage
ADC supply voltage
DVSS
DVDD
DVDD
AVSS
AVDD
DVDD2
DVDD2
DVDD2
DVDD2
DVDD2
DVDD2
DVDD2
DVDD2
DVDD2
DVDD2
DVDD2
DVDD2
DVDD2
AVDD
AVDD
AVDD
DVDD2
DVDD2
STLC60134S
Table 3. Pin Functions (continued)
28
34
35
41
42
51
52
54
58
61
62
SPARES
3
4
5
6
29
30
1
AVDD4
AVSS4
AVSS5
AVDD5
AVDD6
AVSS6
AVSS2
AVDD2
AVDD1
AVSS1
DVSS2
NU3
NU2
NU1
NU0
NC0
NC1
TX pre - drivers supply
AVDD
AVSS
AVSS
AVDD
AVDD
AVSS
AVSS
AVDD
AVDD
AVSS
DVSS
CT filter supply
LNA supply
DAC and support circuit
XTAL oscillator supply voltage
Not
Not
Not
Not
used inputs
used inputs
used inputs
used inputs
DVSS
DVSS
DVSS
DVSS
LT ↔ AUT-C; NT ↔ ATU-R
Figure 3. Grounding and Decoupling Networks.
10µF
VRAP pin
VRAN pin
ANALOG
VDD
10µF
100nF
10µF
100nF
10µF
100nF
VREF pin
4.7µH
L1
10µF
IREF pin
100nF
AVDD (each pin must
have its own capacitor)
100nF
100nF
VCOC pin
10µF
AGND pin
100nF
10µF
D98TL356
ATU-C END: BLOCK DIAGRAM
The transformer at ATU-C side has 1:2 ratio. The
termination resistors are 12.5Ω in case of 100Ω
lines.
The hybrid bridge resistors should be < 2.5kΩ for
low-noise.
An HP filter must be used on the TX path to re-
duce DMT sidelobes and out of band noise influence on the receiver. On the RX path, a LP filter
must be used in order to reduce the echo signal
level and to avoid saturation of the input stage of
the receiver.
The POTS filter is used in both directions to reduce crosstalk between STLC60134S signals
and POTS speech and signalling.
5/22
STLC60134S
Figure 4. ATU-C END Block Diagram.
POTS
35.328MHz
LINE
Zo=100
LP
POTS FILTER
MASTER CLOCK
35.328MHz
2:1
XTRAL
DRIVER
HP POTS FILTER
RXT1
NIBBLES 17.664MHz
WORD 8.832/4.416MHz
RXT2
R
RXP(0:1)
R
0..31dB
4
12.5
12.5
GRX
LNA
LPF
LP138KHz
SC2
12-bit A/D
CONVERTER
CTRLIN
LTNT=1
RXN(0:1)
2R
RXn
8.832MS/s
4.416MS/s
RESETN
2R
GTX
LINE
DRIVER
TO
STLC60135
-15..0dB
TXP
4
PD
HPF
LP 1.1MHz
HC2
12-bit D/A
CONVERTER
TXn
8.832MS/s
4.416MS/s
TXN
D98TL357mod
ATU-R END: BLOCK DIAGRAM
The ATU-R side block diagram is equal to the
ATU-C side block diagram with the following differences:
- The transformer ratio is 1:1
- Termination resistors are 50Ω for 100Ω lines.
An LP filter may be used on the TX path to re-
duce DMT sidelobes and out of band noise influence on the receiver. On the RX path, a HP filter
must be used in order to reduce the echo signal
level and to avoid saturation of the input stage of
the receiver.
The POTS filter is used in both directions to reduce crosstalk between ADSL signals and POTS
speech and signalling. Low pass POTS filter can
be very simple for Lite - ADSL application
Figure 5. ATU-R END Block Diagram.
POTS
35.328
MHz
LINE
Zo=100
LP
POTSFILTER
VCXOUT
MASTER CLOCK
35.328MHz
1:1
VCODAC
XTAL
DRIVER
NIBBLES 17.664MHz
HP POTS FILTER
RXT1
WORD 8.832/4.416MHz
RXT2
R
R
RXP(0:1)
0. .31dB
4
50
50
GRX
LNA
HPF
LP 1.1MHz
HC2
12- bit A/D
CONVERTER
CTRLIN
LTNT=0
RXN(0:1)
2R
RXn
8.832MS/s
4.416MS/s
RESETN
2R
GTX
LI NE
DRIVER
-15..0dB
TXP
4
PD
LPF
LP 138KHz
SC2
12-bit D/A
CONVERTER
TXn
8.832MS/s
4.416MS/s
TXN
D98TL358mod
6/22
TO
STLC60135
STLC60134S
RX PATH
Speech filter
An external bi-directional LC filter for up and
downstream POTS service splits the speech signal from the ADSL signal to the POTS circuits on
ATU-C.
The ADSL analog front end integrated circuit
does not contain any circuitry for the POTS service but it guarantees that bandwidth is not disturbed by spurious signals from the ADSL-spectrum.
Channel Filters
The external analog circuits provide partial echo
cancellation by an analog filtering of the receive
signal for both ATU-R (Reception of downstream
channel) and ATU-C (Reception of upstream
channel). This is feasible because the upstream
and the downstream data can be modulated on
separate carriers (FDM).
Line Noise Model
The power spectral density of the crosstalk noise
sources as described in ANSI document is given
in the figure below (no HDB3 interferer signals).
Also given in dotted line, is the noise model used
in this document to specify the sensivity requirements which are stronger than the original ones.
the frequency band of interest. The maximum
noise density within the pass band can exceed
the average value as follows:
ATU-R RX path (max AGC setting):
<100nVHz-1/2 @ 138kHz
<31nVHz-1/2 for 250kHz < f
ATU-C RX path (max AGC setting):
<100nVHz-1/2 for 34.5kHz < f <138kHz
RX-PATH NOISE AT MINIMUM GAIN
At the minimum AGC the total average thermal
noise of the analog RX-path at the ADC input
should be lower than the ADC quantisation noise.
The maximum noise density within the pass band
can exceed the average value as follows:
ATU-R RX path (min AGC setting):
<500nVHz-1/2 @ 138kHz < f
ATU-C RX path (min AGC setting):
<1.5µVHz-1/2 @ 34.5kHz < f < 138kHz
These noise specifications correspond with 10bit
resolution of the complete RX-path.
Table 4. RX Common-mode Voltage
Description
Common mode signal VCM
at RXIN1 and RXIN2:
Value/Unit
1.6V < VCM <1.7V
Figure 6. Crosstalk PSD.
AGC of RX path
The AGC gain in the RX-path is controlled
through a 5-bits digital code.
Four inputs are provided for RX input and the selection is made with the RXMUX bits of the
CTRLIN interface. This can be used to make
lower gain paths in case of high input signal.
dBm/Hz
-100
-110
-120
-130
-140
D98TL359
79.5 138
250
795
kHz
Signal to Noise Performance
RX- PATH SENSITIVITY AT MAXIMUM GAIN
The RX path sensitivity at the maximal RX-AGC
of the ATU-R receiver is defined at -140dBm/Hz
(for 100Ω ref) on the line. This figure corresponds
to the equivalent input noise of 31nVHz-1/2 seen
on the line.
The sensitivity at the maximal RX - gain of the
ATU-C receiver is defined at -130dBm/Hz (for
100Ω ref) on the line. The figure corresponds to
the equivalent input noise of 100nVHz-1/2 seen
on the line.
Both noise figures include the noise of the hybrid.
It is the equivalent average thermal noise over
Table 5. AGC Characteristics.
Description
Input referred noise
(max. gain)
Max. input level
Max. output level
Gain range
Gain and step accuracy
Value/Unit
20nVHz -1/2
1Vpd
1Vpd
0 to 31dB with step = 1dB
± 0.3dB
RX Filters
The combination of the external filter (an LC ladder filter typically) with the integrated lowpass filter must provide:
- echo reduction to improve dynamic range
- DMT sidelobe and out of band (anti-aliasing)
attenuation.
- Anti alias filter (60dB rejection @ image freq.)
7/22
STLC60134S
ATU-R RX Filters
The integrated filter have the following characteristics:
Table 6. Integrated HC Filter Characteristics
Description
Value/Unit
Input referred noise
100nVHz-1/2
Max. input level
1Vpd
Max. output level
1Vpd
Type
3rd order butterworth
Frequency band
1.104MHz (0%setting, see below)
Frequency tuning
-43.75% -> +0%
Max. in-band ripple
1dB
Matlab Model
Default cut off frequency @ -3dB
Actual cut off @ -3dB
HC Freq. selection register
[B, A] = butter (3, w0, ’s’)
F0 = 1560KHz
w0 = 2 * pi * F0/((20 + n)/16)
n = -4,..,3
see (AFE settings ,Table 22)
Table 7. Phase Characteristic
Description
Value/Unit
Total RX filter group delay
< 50µs @ 138kHz < f < 1.104MHz
TotalRX filter group delay distortion
< 15µs @ 138kHz < f < 1.104MHz
Figure 7. HC Filter Mask for ATU-R RX and ATU-C TX
AMPLITUTDE
+/-1dB
5dB
0dB
30
D98TL360
1104 2208
7728
36dB
50dB
16560
kHz
Note: The total ATU_R RX path (including ADC) group delay distortion is 16µs (i.e. = 15µs + 1µs of ADC)
ATU-C RX filter
This filter is the same as the one used for ATU-R TX.
Linearity of RX
Linearity of the RX analog path is defined by the IM3 product of two sinusoidal signals with frequencies
f1 and f2 and each with 0.5Vpd amplitude (total ≤ 1Vpd) at the output of the RX - AGC amplifier (i.e: before the ADC) for the case of minimal AGC setting.
The following tables 8 and 9 list the RX path intermodulation distortion (as S/IM3 ratio) in downstream
and upstream bandwidth.
Table 8. Linearity of ATU-R RX
f1 (0.5Vpd)
f2 (0.5Vpd)
300kHz
200kHz
S/IM3 (AGC = 0dB)
59.5dB @
53.5dB @
43.5dB @
42.5dB @
8/22
100kHz
400kHz
700kHz
800kHz
500kHz
400kHz
700kHz
600kHz
59.5dB @ 300kHz
48.0dB @ 600kHz
48.0dB @ 500kHz
42.5dB @ 800kHz
STLC60134S
Table 9. Linearity of ATU-C RX
f1 (0.5Vpd)
f2 (0.5Vpd)
S/IM3 (AGC = 20 dB)
80kHz
70kHz
56.5dB @ 60kHz
56.5dB @ 90kHz
2f2 - f1
2f1 - f2
Table 10. RX Filter to A/D Interface
RX filter to A/D maximal level:
1Vpd = full scale of A/D
Table 11. A/D Convertors (A pipeline architecture is used for A/D convertors).
Numbers of bits:
12bits
Minimum resolution of the A/D convertor
11bits
Linearity error of the A/D convertor
<1LSB (out of 12bits)
Full scale input range:
1 Vpdif ±5%
Sampling rate:
8.832MHz (or 4.416MHz in OSR = 2 mode)
Maximum attenuation at 1.1MHz:
<0.5dB without in-band ripple
Maximum group delay:
<3µs
Maximum group delay distortion:
<1µs
Power Supply Rejection
The noise on the power supplies for the RX path must be lower than the following:
<50mVrms in band white noise for any AVDD.
In this case, PSR (power supply rejection) of STLC60134S RX path is lower than -43dB.
TX PATH
Transmitter Spectral Response
The two figures below show the ANSI spectral response mask for ATU-C and ATU-R transmitters
Figure 8. ATU-C TX spectral response mask
+/-3dB
dBm/Hz
24dB
-40
50dB
-64
-90
30
D98TL361
1104 2208
11040
KHz
Figure 9. ATU-R TX spectral response mask
+/-3dB
dBm/Hz
24dB
-40
48dB
-64
-88
30
D98TL362
138
181
224
KHz
9/22
STLC60134S
Table 12. AGC of TX Path (from filter output to TXP and TXN).
Output noise
25mVHz-1/2
Input level (nominal)
1Vpd
Output level nominal, full-scale
1.5Vpd
Maximum Output Load
> 500Ω; <10pF
AGC range:
-15dB...dB
AGC step:
1dB
Gain and step accuracy
±0.3dB
Minimum code (0000) stands for AGC = -15dB and maximum (1111 - MSB left) for AGC = 0dB (See Tx
setting, Table22).
TX Pre-driver Capability
The pre-driver drives an external line power amplifier which transmits the required power to the line.
Table 13. TX Pre-driver
TX drive level to the external line driver for max. AGC setting
1.5 Vpdif
External line driver input impedance:
resistive
capacitive
> 500Ω
< 30pF
Pre-driver characteristics:
closed loop gain:
-15dB...0dB with step = 1dB
ooutput impedance:
output offset voltage (0dB)
< 10mV
input noise voltage (0dB)
< 20nVHz-1/2 @ f > 250kΩ
< 50nVHz-1/2 @ 34.5K < f
<138kΩ
output common mode voltage:
1.6V < Vcm < 1.7V
TX Filter
The TX filters act not only to suppress the DMT sidebands but also as smoothing filters on the D/A convertor’s output to suppress the image spectrum. For this reason they must be realized in a continuous
time approach.
ATU-R TX Filter
The purpose of this filter is to remove out-of-band noise of the ATU-R TX path echoed to the ATU-R RX
path. In order to meet the transmitter spectral response, an additional filtering must be (digitally) performed. The integrated filter has the following characteristics:
Table 14. Integrated SC Filter Characteristics
Description
Value/Unit
-1/2
Input referred noise
100nVHz
Max. input level
1Vpd
Max. output level
1Vpd
Type
4th order chebytchef
Frequency band
138kHz (0% setting see below)
Frequency tuning
-25% -> +25%
Max. in-band ripple
1dB
Matlab Model
Default cut-off frequency @ -3dB
Actual cut-off @ -3dB
SC Freq. selection register
[B,A] = cheby1 (4,0.5,W0,’s’) {ripple = 0.5}
F0 = 151.8kHz
W0 = 2*pi*F0/((17+n)/16)
n = -4,..,3
see (AFE settings, Table 22)
10/22
STLC60134S
Table 15. Phase characteristics
Description
Value/Unit
Total TX filter group delay
<50µs @ 34.5kHz < f < 138kHz
Total TX filter group delay distortion
<20µs @ 34.5kHz < f < 138kHz
Note: The total ATU-R TX path (including DAC) group delay distortion is 16µs (i.e. = 15µs + 1µs of DAC)
Figure 10. SC Filter Mask for ATU-CRX and ATU-R TX
AMPLITUTDE
+/-1dB
20dB
0dB
30
D98TL363
138
250
KHz
Table 16. D/A Convertor (A current steering architecture is used).
Description
Numbers of bits:
Value/Unit
12bits
Minimum resolution of the D/A convertors
11bits
Linearity error of the A/D convertor
<1LSB (out of 12bits)
Full scale input range:
1 Vpdif ±5%
Sampling rate:
8.832MHz (or 4.416MHz in compatible mode)
Maximum group delay:
<3µs
Maximum group delay distortion:
<1µs
Linearity of ATU-C TX
Linearity of the TX is defined by the IM3 product of two sinusoidal signals with frequencies f1 and f2 and
each with 0.5Vpd amplitude (total ≤ 1Vpd) at the output of the pre-driver for the case of a total AGC = 0dB.
Table 17. Linearity of ATU-C TX
f1 (0.5Vpd)
f2 (0.5Vpd)
S/IM3 (AGC = 0dB)
300kHz
200kHz
59.5dB @ 100kHz
53.5dB @ 400kHz
43.5dB @ 700kHz
42.5dB @ 800kHz
500kHz
400kHz
59.5dB @ 300kHz
48.0dB @ 600kHz
700kHz
600kHz
48.0dB @ 500kHz
42.5dB @ 800kHz
11/22
STLC60134S
Linearity of ATU-R TX
Table 18. Linearity of ATU-R TX
f1 (0.5Vpd)
f2 (0.5Vpd)
S/IM3 (AGC = 0 dB)
80kHz
70kHz
59.5dB (@ 60KHz, 90KHz)
TX IDLE CHANNEL NOISE
ATU-C TX idle channel noise
The idle channel noise specifications correspond with 11bit resolution of the complete TX-path. ATU-C
TX idle channel output noise on TX.
Table 19. ATU-C TX idle channel noise
For max AGC setting (0dB)
In-band noise
Out-of-band noise
For min AGC setting (=-15dB)
In-band noise
500nVHz-1/2
500nVHz-1/2
80nVHz
-1/2
@ 138kHz -1.104MHz
@ 34.5kHz -138kHz
@ 138kHz -1.104MHz
ATU-R TX idle channel noise
ATU-R TX idle channel output noise on TXP, TXN
Table 20. ATU-R TX idle channel noise
For max AGC setting (0dB)
In-band noise
Out-of-band noise
1.6µVHz-1/2
-1/2
1.6µVHz
150nVHz-1/2
@ 34.5kHz -138kHz
@ 138kHz
@ 250kHz -1.104MHz
500nVHz-1/2
@ 34kHz -138kHz
For min AGC setting (=-15dB)
In-band noise
Power Supply Rejection
The noise on the power supplies for the TX-path must be lower than the following:
< 50mVrms in-band white noise for AVDD.
< 15mVrms in-band white noise for Pre-driver AVDD.
VCXO
A voltage controlled crystal oscillator driver is integrated in STLC60134S. The nominal frequency is
35.328MHz. The quartz crystal is connected between the pins XTALI and XTALO.
The principle of the VCXO control is shown in figure 11.
The information coming from the digital processor via the CTRLIN path is used to drive an 8-bit DAC
which generates a control current. This current is externally converted and filtered to generate the required control voltage (range:-15V to 0.5V) for the varicap. The VCXO circuit characteristics are given in
Table 21.
12/22
STLC60134S
Table 21. VCXO circuit Characteristics
Symbol
fabs
frange
IO
Ii
Parameter
Absolute frequency accuracy
Frequency Tuning Range
VCXO Output Current
Min.
-15ppm
Reference Input Current
100µA
Nominal
35.328MHz
±50ppm
100µA
Max.
+15ppm
Note
Rref = 16.5kΩ
AVDD = 3.3V
AVDD = 3.3V
1mA
N.B: frequency tuning range is proportional to the crystal dynamic capacitance Cm.
Figure 11. Principle of VCXO control
AVDD
CS
VCOCX
IVCO
1MΩ
8 bits
CTRLIN
DAC
AVDD/22÷AVDD/2
RR EF
AVDD
Ii
±30%
IO =Ii
Filtered VCXO
(se e CTRLIN table)
VCXOUT
AGND
Clk35
XTALO
CP
Rt
Ct
-15V
XTALI
D98TL364mod
The tuning must be monotonic with 8-bit resolution with the worst-case tuning step of <2ppm/LSB (8-bit).
The time constant of the tuning must be variable from 5s to 10s through an external capacitor Cs (R =
1MΩ ±30%). This determines the speed of the VCXO in normal operation (slow speed in ”show time”)
with filtered VCXO. For faster tracking, the previous filter is not used and the speed depends on CtRt.
13/22
STLC60134S
DIGITAL INTERFACE
Control Interface
The digital setting codes for the STLC60134S configuration are sent over a serial line (CTRLIN) using
the word clock (CLWD).
The data burst is composed of 16 bits from which the first bit is used as start bit (’0’), the three LSBs being used to identify the data contained in the 12 remaining bits. Test related data are overruled by the
normal settings if the TEST pin is low.
Table 22. Control Interface Bit Mapping
M
S
B
b
1
5
0
0
0
0
0
0
0
0
0
0
0
0
b
1
5
0
0
0
0
0
0
0
0
0
b
1
5
0
0
0
0
0
0
0
0
b
1
4
x
b
1
3
b
1
2
b
1
1
b
1
0
b
9
b
8
b
7
b
6
b
5
b
4
b
3
b
2
b
1
L
S
B
b
0
0
0
0
0
0
0
0
0
0
0
0
0
b
1
0
0
0
0
0
0
0
0
0
0
0
0
b
0
External Gain Control GC1
(init = 0)
External Gain Control GC0
(init = 0)
Rx input selected = RXIN0, RXIP0
(init)
Rx input selected = RXIN1, RXIP1
AGC RX Gain setting 0dB
(init)
AGC RX Gain setting 1dB
AGC RX Gain setting XdB
AGC RX Gain setting 31dB
Normal mode Filter selection see LTNT pin (init)
In ATU-C conf, force HC2 for RX path, TX grounded
In ATU-C conf, force HC1 for RX path
Normal mode Filter selection see LTNT pin
b
3
0
0
0
0
0
0
0
0
0
0
0
0
b
2
0
0
0
0
0
0
0
0
0
b
1
1
1
1
1
1
1
1
1
1
b
0
Transmit TX - AGC setting -15dB
Transmit TX - AGC setting -14dB
Transmit TX - AGC setting (X - 15) dB
Transmit TX - AGC setting 0dB
Not used
Not used
Not used
Not used
General Purpose Output (GPO) setting
b
3
0
0
0
0
0
0
0
0
0
b
2
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
0
0
0
0
0
0
0
0
Normal Mode (Digital path)
(init)
Digital Loopback (digital TX to digital RX - DAC not used)
Normal Mode (Analog path)
Analog loopback (RXi to TXi - ADC not used) 1) (init)
VCO DAC disabled
VCO DAC enabled
(init)
HC filter enabled
(init)
HC filter enabled
x
0
1
0
0
x
1
b
1
4
0
0
x
1
b
1
4
0
1
b
1
3
0
0
x
1
b
1
3
b
1
2
0
0
x
1
b
1
2
b
1
1
0
1
x
1
b
1
1
0
1
0
1
0
1
0
0
x
1
b
1
0
0
0
x
1
b
9
0
0
x
1
b
8
0
1
x
1
b
7
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
b
1
0
b
9
b
8
b
7
0
0
1
1
b
6
x
b
6
0
1
0
1
b
5
x
b
5
b
4
x
b
4
RX SETTINGS
TX SETTINGS
(init)
(init)
(init)
(init)
(init = 000)
AFE SETTINGS
1) After initialization, this bit has to be cleared (0) to make the device properly operate.
14/22
(init)
STLC60134S
Table 22. Control Interface Bit Mapping (continued)
b
1
5
0
0
0
0
0
0
0
0
0
b
1
5
0
0
0
b
1
5
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
b
1
5
0
0
0
b
1
4
b
1
3
b
1
2
b
1
1
b
1
0
0
1
b
9
1
0
1
b
8
1
1
0
b
7
b
6
b
1
3
0
x
1
b
1
3
b
1
2
0
x
1
b
1
2
b
1
1
0
x
1
b
1
1
b
1
0
0
x
1
b
1
0
b
4
b
3
b
2
b
1
b
0
0
1
b
3
0
0
0
0
0
0
0
0
0
b
2
1
1
1
1
1
1
1
1
1
b
1
0
0
0
0
0
0
0
0
0
b
0
OSR set to 4
OSR set to 2
SC freq. selection: Fc = 138kHz
SC freq. selection: Fc ~ 110kHz
SC freq. selection: Fc ~ 170kHz
HC freq. selection: Fc = 1.104MHz
HC freq. selection: Fc ~ 768kHz
VCXO output NOT filtered (”show-time”)
VCXO output filtered
1
1
1
b
1
1
1
1
b
0
VCO DAC CURRENT value @ MINIMUM
VCO DAC CURRENT value @ X
VCO DAC CURRENT value @ MAXIMUM
b
3
0
0
0
b
2
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
b
2
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
b
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
b
0
TXD Active
TXD in powerdown
N.U.
N.U.
ADC Active
ADC in powerdown
HFC2 Active
HFC2 in powerdown
HFC1 Active
HFC1 in powerdown
SCF2 Active
SCF2 in powerdown
SCF1 Active
SCF1 in powerdown
LNA Active
LNA in powerdown
DAC Active
DAC in powerdown
DACE Active
DACE in powerdown
VCODAC Active
VCODAC in powerdown
XTAL Active
XTAL in powerdown
1
1
1
0
1
1
1
0
1
RESERVED
RESERVED
RESERVED
1
1
1
1
0
b
1
4
0
x
1
b
1
4
0
1
b
5
b
9
b
8
b
7
0
x
1
b
9
0
x
1
b
8
0
x
1
b
7
b
6
b
6
0
1
b
5
b
5
0
1
b
4
b
4
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
b
1
4
x
x
x
b
1
3
x
x
x
b
1
2
x
x
x
b
1
1
x
x
x
b
1
0
x
x
x
b
9
b
8
b
7
b
6
b
5
b
4
0
1
b
3
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
x
AFE SETTINGS
(init)
(init) (*)
(*)
(*)
(init) (*)
(*)
(init)
VCO DAC VALUE SETTINGS
POWER DOWN ANALOG BLOCK SETTINGS
(init)
(init)
(init)
(init)
(init)
(init)
(init)
(init)
(init)
(init)
(init)
(init)
RESERVED
(*) For each filter, 8 possible frequency values (see table 6 and table 14). Notation is 2’s complement range from -4 = 100b +3 = 011b.
Fc is the frequency band (-1dB)
15/22
STLC60134S
Control Interface Timing
The word clock (CLWD) is used to sample at negative going edge the control information. The start bit b15
is transmitted first followed by bits b[14:0] and at least 16 stop bits need to be provided to validate the data.
Figure 12. Control Interface.
CLWD
CTRLIN
START
BIT
DATA
ID.
D98TL365
>=16 STOP BITS=HIGH
Data set-up and hold time versus falling edge CLWD must be greater than 10nsec.
Receive / Transmit Interface
RECEIVE / TRANSMIT PROTOCOL
The digital interface is based on 4 x 8.832MHz (35.328MHz) data lines in the following manner:
If OSR = 2 (OSR bit set to 1) is selected, CLKNIB is used as nibble clock (17.664MHz, disabled in normal
mode), and all the RXi, TXi, CLKWD periods are twice as long as in normal mode. This ensures a compatibility with lower speed products.
TX Signal Dynamic
The dynamic of data signal for both TX DACs is 12 bits extracted from the available signed 16 bit representationcoming from the digital processor.
The maximal positive number is 214-1, the most negative number is -214, the 3 LSBs are filled with ’0’.
Any signal exceeding these limits is clamped to the maximum value.
Table 23.
BIT MAP/NIBBLE
N0
N1
N2
N3
TXD0
not used
data bit 1
data bit 5
data bit 9
TXD1
not used
data bit 2
data bit 6
data bit 10
TXD2
not used
data bit 3
data bit 7
data SIGN
TXD3
d0 = data bit 0 (LSB)
data bit 4
data bit 8
data SIGN
Table 24. TX bit map
N3
sign
sign
N2
d10
d9
The two sign bits must be identical.
16/22
d8
d7
N1
d6
d5
d4
d3
N0
d2
d1
d0
n.u.
n.u.
n.u.
STLC60134S
RX Signal Dynamic
The dynamic of the signal from the ADC is limited to 13bits. Those bits are converted to a signed (2’s
complement) representation with a maximal positive number of 214 -1 and a most negative number -214.
The 2 LSBs are filled with ’0’.
Table 25.
BIT MAP/NIBBLE
N0
N1
N2
N3
RXD0
0
data bit 2
data bit 6
data bit 10
RXD1
0
data bit 3
data bit 7
data bit 11
RXD2
d0 = data bit 0 (LSB)
data bit 4
data bit 8
data SIGN
RXD3
data bit 1
data bit 5
data bit 9
data SIGN
Table 26. RX bit map
N3
sign
sign
N2
d11
d10
d9
d8
N1
d7
d6
d5
d4
N0
d3
d2
d1
d0
0
0
The two sign bits must be identical.
Figure 13. TX/ RX Digital Interface Timing
CLKM
35.328MHz
CLWD
8.832MHz
TXDx/RXDx
N0
N1
N2
N3
OSR=4
CLKNIB
17.664MHz
CLWD
4.416MHz
TXDx/RXDx
N0
D98TL366
N1
N2
N3
OSR=2
Receive / Transmit interface timing
The interface is a triple (RX, TX) nibble - serial interface running at 8.8MHz sampling (normal mode).
The data are represented in 16bits format, and transferred in groups of 4 bits (nibbles). The LSBs are
transferred first. The STLC60134S generates a nibble clock (CLKM master clock in normal mode,
CLKNIB in OSR = 2 mode) and word signals shared by the three interfaces.
Data is transmitted on the rising edge of the master clock (CLKM/CLKNIB) and sampled on the falling
edge of CLKM/CLKNIB. This holds for the data stream from STLC60134S and from the digital processor.
Data, CLWD setup and hold times are 5ns with reference to the falling edge of CLKM/CLKNIB.
(not floating).
17/22
STLC60134S
Data is transmitted on the rising edge of the master clock (CLKM/CLKNIB) and sampled on the low going
edge of CLKM/CLKNIB. This holds for the data stream from STLC60134S and from the digital processor.
Data,CLWD setup and hold times are 5ns with reference to thefalling edgeof CLKM/CLKNIB. (not floating).
POWER DOWN
When pin Pdown = ”1”, the chip is set in power down mode. As the Pdown signal is synchronously sampled, minimum duration is 2 periods of the 35MHz clock. In this mode all analog functional blocks are
deactivated except: preamplifiers (TX), clock circuits for output clock CLKM. Pdown will not affect the digital part of the chip. Anyway, after a Pdown transition, the digital part status, is updated after 3 clock periods (worst case)
The chip is activated when Pdown = ”0”.
In power down mode the following conditions hold:
- Output voltages at TXP/TXN = AGND
- Preamplifier is on with maximum gain setting (0dB), (digitalgain setting coefficients are overruled)
- The XTAL outputclock on pin CLKM keepsrunning.
- All digital setting are retained.
- Digital output on pins RXDx don’t care (not floating).
In power-down mode the power consumption is 100mW.
Following external conditions are added:
- Clock pin CLW is running.
- CTRLIN signals can still be allowed.
- AGND remains at AVDD/2 (circuit is powered up)
- Input signal at TXDx inputs are not strobed.
The Pdown signal controls asynchronously the power-down of each analog module:
- After a few µs the analog channel is functional
- After about 100ms the analog channel delivers full performance
RESET FUNCTION
The reset function is implied when the RESETN pin is at a low voltage input level. In this condition, the
reset function can be easily used for power up reset conditions.
Detailed Description
During reset: (reset is asynchronous, tenths of ns are enough to put the IC in reset)
All clock outputs are deactivatedand put to logical ”1” (except for the XTAL and master clock CLKM)
After reset: (4 clock periods after reset transition, as worst case)
- OSR = 4
- All analog gains (RX, TX) are set to minimum value
- Nominal filter frequency bands(138kHz, 1.104Hz)
- LNA input = ”11” (max. attenuation)
- VCO dac disabled
- Depending of the LTNT pin value the following configuration is chosen:
’0’ (ATU-R)
RX:
TX:
LNA -> HC2 -> ADC
DAC -> SC2 -> TX
’1’ (ATU-C)
RX:
TX:
18/22
LNA -> SC2 -> ADC
DAC -> HC2 -> TX
STLC60134S
Digital outputs are placed in don’t care condition (non-floating).
N.B. If a Xtal oscillator is used, the RESET must be released at last 10µs after power-on, to ensure a
correct duty cycle for the clk35 clock signal.
ELECTRICAL RATINGS AND CHARACTERISTICS
Table 27. Absolute Maximum Ratings
Symbol
Parameter
Min
Max
Unit
VDD
Any VDD Supply Voltage, related to substrate
- 0.5
5
V
Vin
Voltage at any input pin
-0.5
VDD +0.5
V
Tstg
Storage Temperature
-40
125
°C
TL
Lead Temperature (10 second soldering)
300
°C
ILU
Latch - up current @80°C
100
mA
IAVDD
Analog Supply Current @ 3.6V - normal operation
165
mA
IAVDD
Analog Supply Current @ 3.6V - power down
30
mA
IDVDD
Analog Supply Current @ 3.6V - normal operation
56
mA
IDVDD
Analog Supply Current @ 3.6V - power down
50
mA
Table 28. Thermal Data
Symbol
Rth j-amb
Parameter
Thermal and Junction ambient
Value
Unit
50
°C/W
Table 29. Operating Conditions
(Unless specified, the characteristic limits of ’Static Characteristics’ in this document apply over an Top =
-40 to 80 °C; VDD within the range 3 to 3.6V ref. to substrate.
Symbol
Parameter
Min
Max
Unit
AVDD
AVDD Supply Voltage, related to substrate
3.0
3.6
V
DVDD
DVDD Supply Voltage, related to substrate
2.7
3.6
V
Vin /Vout
Voltage at any input and output pin
0
VDD
V
Power Dissipation
0.4
0.6
W
Tamb
Ambient Temperature
-40
80
°C
Tj
Junction Temperature
-40
110
°C
Pd
19/22
STLC60134S
STATIC CHARACTERISTICS
Table 30. Digital Inputs
Schmitt-trigger inputs: TXi, CTRLIN, PDOWN, LTNT, RESETN, TEST
Symbol
Parameter
V IL
Low Level Input Voltage
VIH
High Level Input Voltage
VH
Hysteresis
C imp
Test Condition
Min.
Typ.
Max.
Unit
0.3 ⋅ DVDD
V
0.7 ⋅ DVDD
V
1.0
Input Capacitance
1.3
V
3
pF
Max.
Unit
0.15 ⋅ DVDD
V
Table 31. Digital Outputs
Hard Driven Outputs: RXi
Symbol
Parameter
Test Condition
V OL
Low Level Output Voltage
Iou t = -4mA
VOH
High Level Output Voltage
Iou t = 4mA
Cload
Load Capacitance
Min.
Typ.
0.85 ⋅ DVDD
V
30
pF
Max.
Unit
0.15 ⋅ DVDD
V
Clock Driver Output: CLKM, CLNIB, CLKWD
Symbol
Parameter
Test Condition
V OL
Low Level Output Voltage
Iou t = -4mA
VOH
High Level Output Voltage
Iou t = 4mA
Cload
Load Capacitance
DC
Duty Cycle
20/22
Min.
Typ.
0.85 ⋅ DVDD
45
V
30
pF
55
%
STLC60134S
mm
DIM.
MIN.
inch
TYP.
MAX.
A
MIN.
TYP.
1.60
A1
0.05
A2
1.35
B
C
0.063
0.15
0.002
0.006
1.40
1.45
0.053
0.055
0.057
0.18
0.23
0.28
0.007
0.009
0.011
0.12
0.16
0.20
0.0047 0.0063 0.0079
D
12.00
0.472
D1
10.00
0.394
D3
7.50
0.295
e
0.50
0.0197
E
12.00
0.472
E1
10.00
0.394
E3
7.50
0.295
L
0.40
0.60
L1
0.75
OUTLINE AND
MECHANICAL DATA
MAX.
0.0157 0.0236 0.0295
1.00
0.0393
TQFP64
0°(min.), 7°(max.)
K
D
D1
A
D3
A2
A1
48
33
49
32
0.10mm
E
E1
E3
B
B
Seating Plane
17
64
1
16
C
L
L1
e
K
TQFP64
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STLC60134S
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