ATMEL TSEV8388BFZA2

Features
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8-bit Resolution
ADC Gain Adjust
1.5 GHz Full Power Input Bandwidth (-3 dB)
1 GSPS (min) Sampling Rate
SINAD = 44.3 dB (7.2 Effective Bits), SFDR = 58 dBc,
at FS = 1 GSPS, FIN = 20 MHz
SINAD = 42.9 dB (7.0 Effective Bits), SFDR = 52 dBc,
at FS = 1 GSPS, FIN = 500 MHz
SINAD = 40.3 dB (6.8 Effective Bits), SFDR = 50 dBc,
at FS = 1 GSPS, FIN = 1000 MHz (-3 dB FS)
2-tone IMD: -52 dBc (489 MHz, 490 MHz) at 1 GSPS
DNL = 0.3 lsb, INL = 0.7 lsb
Low Bit Error Rate (10-13) at 1 GSPS
Very Low Input Capacitance: 3 pF
500 mVpp Differential or Single-ended Analog Inputs
Differential or Single-ended 50Ω ECL Compatible Clock Inputs
ECL or LVDS/HSTL Output Compatibility
Data Ready Output with Asynchronous Reset
Gray or Binary Selectable Output Data; NRZ Output Mode
Power Consumption: 3.4W at Tj = 70°C Typical
Radiation Tolerance Oriented Design (150 Krad (Si) measured)
Two Package Versions
Evaluation board: TSEV8388B
Demultiplexer TS81102G0: Companion Device Available
ADC 8-bit
1 GSPS
TS8388B
Applications
•
Digital Sampling Oscilloscopes
•
Satellite Receiver
•
Electronic Countermeasures/Electronic Warfare
•
Direct RF Down-conversion
Description
The TS8388B is a monolithic 8-bit analog-to-digital converter, designed for digitizing
wide bandwidth analog signals at very high sampling rates of up to 1 GSPS.
The TS8388B uses an innovative architecture,
including an on-chip Sample and Hold (S/H),
and is fabricated with an advanced
high speed bipolar process.
The on-chip S/H has a 1.5 GHz full power
input bandwidth, providing excellent dynamic
performance in undersampling applications
(High IF digitizing).
Rev. 2144C–BDC–04/03
1
Functional
Description
Block Diagram
The following figure shows the simplified block diagram.
Figure 1. Simplified Block Diagram
GAIN
MASTER/SLAVE TRACK & HOLD AMPLIFIER
VIN, VINB
G=2
T/H
G=1
T/H
G=1
RESISTOR
CHAIN
ANALOG
ENCODING
BLOCK
4
INTERPOLATION
STAGES
5
4
REGENERATION
LATCHES
5
4
ERROR CORRECTION &
DECODE LOGIC
CLK, CLKB
CLOCK
BUFFER
8
OUTPUT LATCHES &
BUFFERS
8
DRRB DR, DRB
Functional
Description
GORB
DATA, DATAB OR, ORB
The TS8388B is an 8-bit 1 GSPS ADC based on an advanced high-speed bipolar technology
featuring a cutoff frequency of 25 GHz.
The TS8388B includes a front-end master/slave Track and Hold stage (S/H), followed by an
analog encoding stage and interpolation circuitry.
Successive banks of latches regenerate the analog residues into logical data before entering
an error correction circuitry and a resynchronization stage followed by 75Ω differential output
buffers.
The TS8388B works in fully differential mode from analog inputs up to digital outputs.
The TS8388B features a full-power input bandwidth of 1.5 GHz.
A control pin GORB is provided to select either Gray or Binary data output format.
A gain control pin is provided in order to adjust the ADC gain.
A Data Ready output asynchronous reset (DRRB) is available on TS8388B.
The TS8388B uses only vertical isolated NPN transistors together with oxide isolated polysilicon resistors, which allow enhanced radiation tolerance (no performance drift measured at
150 kRad total dose).
2
TS8388B
2144C–BDC–04/03
TS8388B
Specifications
Absolute
Maximum Ratings
Table 1. Absolute Maximum Ratings
Parameter
Symbol
Positive supply voltage
VCC
Digital negative supply voltage
DVEE
Digital positive supply voltage
VPLUSD
Negative supply voltage
VEE
Maximum difference between negative supply voltage
DVEE to VEE
Analog input voltages
Value
Unit
GND to 6
V
GND to -5.7
V
GND -0.3 to 2.8
V
GND to -6
V
0.3
V
VIN or VINB
-1 to +1
V
Maximum difference between VIN and VINB
VIN - VINB
-2 to +2
V
Digital input voltage
VD
GORB
-0.3 to VCC +0.3
V
Digital input voltage
VD
DRRB
VEE -0.3 to +0.9
V
Digital output voltage
VO
VPLUSD -3 to VPLUSD -0.5
V
Clock input voltage
VCLK or VCLKB
-3 to +1.5
V
Maximum difference between VCLK and VCLKB
VCLK - VCLKB
-2 to +2
V
Maximum junction temperature
Tj
+135
°C
Storage temperature
Tstg
-65 to +150
°C
Lead temperature (soldering 10s)
Tleads
+300
°C
Note:
Comments
Absolute maximum ratings are limiting values (referenced to GND = 0V), to be applied individually, while other parameters are
within specified operating conditions. Long exposure to maximum rating may affect device reliability. The use of a thermal heat
sink is mandatory. See “The board set comes fully assembled and tested, with the TS8388B installed.” on page 42.
Recommended
Operating
Conditions
Table 2. Recommended Operating Conditions
Recommended Value
Parameter
Symbol
Comments
Positive supply voltage
VCC
Positive digital supply voltage
VPLUSD
ECL output compatibility
Positive digital supply voltage
VPLUSD
LVDS output compatibility
Negative supply voltage
VEE, DVEE
Min
Typ
Max
Unit
4.5
+5
5.25
V
–
GND
–
V
+1.4
+2.4
+2.6
V
-5.25
-5
-4.75
V
3
2144C–BDC–04/03
Table 2. Recommended Operating Conditions (Continued)
Recommended Value
Parameter
Symbol
Comments
Min
Typ
Max
Unit
Differential analog input voltage
(Full Scale)
VIN, VINB
VIN - VINB
50Ω differential or single-ended
±113
450
±125
500
±137
550
mV
mVpp
Clock input power level
PCLK, PCLKB
50Ω single-ended clock input
3
4
10
dBm
Operating temperature range
TJ
Commercial grade: “C”
Industrial grade: “V”
Military grade: “M”
Electrical
Operating
Characteristics
°C
0 < Tc; Tj < 90
-40 < Tc; Tj < 110
-55 < Tc; Tj < +125
VEE = DVEE = -5V; VCC = +5V; VIN -VINB = 500 mVpp Full Scale differential input;
Digital outputs 75 or 50Ω differentially terminated;
Tj (typical) = 70°C. Full Temperature Range: up to -55°C < Tc; Tj < +125°C, depending on
device grade.
Table 3. Electrical Specifications
Parameter
Value
Symbol
Test
Level
Min
Typ
Max
Unit
VCC
VPLUSD
VPLUSD
1
4
4
4.5
–
1.4
5
0
2.4
5.5
–
2.6
V
V
V
ICC
IPLUSD
1
1
–
–
420
130
445
145
mA
mA
VEE
1
-5.5
-5
-4.5
V
AIEE
DIEE
1
1
–
–
185
160
200
180
mA
mA
PD
1
–
3.9
4.1
W
PSRR
4
–
0.5
2
mW
VCC
VPLUSD
VPLUSD
1, 2, 6
4
4
4.7
–
1.4
5
0
2.4
5.3
–
2.6
V
V
V
Note
Power Requirements (CBGA68 package)
Positive supply voltage
Analog
Digital (ECL)
Digital (LVDS)
Positive supply current
Analog
Digital
Negative supply voltage
Negative supply current
Analog
Digital
Nominal power dissipation
Power supply rejection ratio
Power Requirements
Power Requirements (CQFP68 packaged device)
Positive supply voltage
Analog
Digital (ECL)
Digital (LVDS)
4
TS8388B
2144C–BDC–04/03
TS8388B
Table 3. Electrical Specifications (Continued)
Value
Test
Level
Min
Typ
Max
Unit
1, 2
6
1, 2
6
–
–
–
–
385
395
115
120
445
445
145
145
mA
mA
mA
mA
VEE
1, 2, 6
-5.3
-5
-4.7
V
Analog
AIEE
Digital
DIEE
1, 2
6
1, 2
6
–
–
–
–
165
170
135
145
200
200
180
180
mA
mA
mA
mA
PD
1, 2
6
–
–
3.4
3.6
4.1
4.3
W
W
PSRR
4
–
0.5
2
mW
–
–
–
8
–
bits
Full Scale Input Voltage range (differential mode)
(0V common mode voltage)
VIN
VINB
4
–
-125
-125
–
–
125
125
mV
mV
Full Scale Input Voltage range (single-ended input
option) (See Application Notes)
VIN
VINB
4
–
-250
–
–
0
250
–
mV
mV
Analog input capacitance
CIN
4
–
3
3.5
pF
Input bias current
IIN
4
–
10
20
µA
Input Resistance
RIN
4
0.5
1
–
MΩ
Full Power input Bandwidth (-3dB)
CBGA68 package
CQFP68 package
FPBW
–
–
–
4
4
–
–
–
–
1.8
1.5
–
–
–
–
GHz
GHz
Small signal input Bandwidth (10% full scale)
SSBW
4
1.5
1.7
–
GHz
Logic compatibility for clock inputs
(See Application Notes)
–
–
ECL or specified clock input
power level in dBm
ECL Clock inputs voltages (VCLK or VCLKB):
–
4
–
–
–
–
Logic “0” voltage
VIL
–
–
–
-1.5
V
Logic “1” voltage
VIH
–
-1.1
–
–
V
Logic “0” current
IIL
–
–
5
50
µA
Logic “1” current
IIH
–
–
5
50
µA
Clock input power level into 50Ω termination
–
–
Clock input power level
–
4
-2
4
10
dBm
Clock input capacitance
CCLK
4
–
3
3.5
pF
Parameter
Symbol
Note
Positive supply current
Analog
ICC
Digital
IPLUSD
Negative supply voltage
Negative supply current
Nominal power dissipation
Power supply rejection ratio
Resolution
(2)
Analog Inputs
–
Clock Inputs
dBm into 50Ω
–
(10)
–
5
2144C–BDC–04/03
Table 3. Electrical Specifications (Continued)
Parameter
Symbol
Test
Level
Value
Min
Typ
Max
Unit
Digital Outputs
Single-ended or differential input mode, 50% clock duty cycle (CLK, CLKB), Binary output data format,
Tj (typical) = 70°C.
(1)(6)
Logic compatibility for digital outputs
(Depending on the value of VPLUSD)
(See Application Notes)
–
–
Differential output voltage swings
(assuming VPLUSD = 0V):
–
4
–
–
–
–
75Ω open transmission lines (ECL levels)
–
–
1.5
1.620
–
V
75Ω differentially terminated
–
–
0.70
0.825
–
V
50Ω differentially terminated
–
–
0.54
0.660
–
V
–
4
–
–
–
–
Logic “0” voltage
VOL
–
–
-1.62
-1.54
V
Logic “1” voltage
VOH
–
-0.88
-0.8
–
V
–
4
–
–
–
–
Logic “0” voltage
VOL
–
–
-1.41
-1.34
V
Logic “1” voltage
VOH
–
-1.07
-1
–
V
–
–
–
–
–
–
Logic “0” voltage
VOL
1, 2
6
–
–
-1.40
-1.40
-1.32
-1.25
V
V
Logic “1” voltage
VOH
1, 2
6
-1.16
-1.25
-1.10
-1.10
–
–
V
V
Differential Output Swing
DOS
4
270
300
–
mV
–
4
–
–
1.6
mV/°C
Output levels (assuming VPLUSD = 0V)
75Ω open transmission lines:
Output levels (assuming VPLUSD = 0V)
75Ω differentially terminated:
Output levels (assuming VPLUSD = 0V)
50Ω differentially terminated:
Output level drift with temperature
Note
ECL or LVDS
–
(6)
(6)
(6)
DC Accuracy (CBGA68 package)
Single-ended or differential input mode, 50% clock duty cycle (CLK, CLKB), Binary output data format
Tj (typical) = 70°C.
Differential non linearity
DNL-
1
-0.6
-0.4
–
lsb
Differential non linearity
DNL+
1
–
0.4
0.6
lsb
Integral non linearity
INL-
1
-1.2
-0.7
–
lsb
Integral non linearity
INL+
1
–
0.7
1.2
lsb
No missing codes
–
Gain
–
1, 2
90
98
110
%
Input offset voltage
–
1, 2
-26
-5
26
mV
6
Guaranteed over specified temperature range
(2)(3)
(2)(3)
(3)
TS8388B
2144C–BDC–04/03
TS8388B
Table 3. Electrical Specifications (Continued)
Parameter
Gain error drift
Offset error drift
Value
Symbol
Test
Level
Min
Typ
Max
Unit
–
–
4
4
100
40
125
50
150
60
ppm/°C
ppm/°C
Note
DC Accuracy (CQFP68 package)
Single-ended or differential input mode, 50% clock duty cycle (CLK, CLKB), Binary output data format
Tj (typical) = 70°C.
Differential non linearity
Differential non linearity
Integral non linearity
Integral non linearity
No missing code
Gain error
Input offset voltage
Gain error drift
Offset error drift
DNL-
1, 2
6
-0.5
-0.6
-0.25
-0.35
–
–
lsb
lsb
DNL+
1, 2
6
–
–
0.3
0.4
0.6
0.7
lsb
lsb
INL-
1, 2
6
-1.0
-1.2
0.7
0.9
–
–
lsb
lsb
INL+
1, 2
6
–
–
0.7
0.9
1.0
1.2
lsb
lsb
–
Guaranteed over specified temperature range
(2)(3)
(2)(3)
(3)
–
1, 2
6
-10
-11
-2
-2
10
11
% FS
% FS
–
1, 2
6
-26
-30
-5
-5
26
30
mV
mV
–
–
4
4
100
40
125
50
150
60
ppm/°C
ppm/°C
BER
4
–
–
1E-12
Error/
sample
(2)(4)
TS
4
–
0.5
1
ns
(2)
TOR
4
–
0.5
1
ns
(2)
(2)
Transient Performance
Bit Error Rate
FS = 1 GSPS FIN = 62.5 MHz
ADC settling time
VIN -VINB = 400 mVpp
Overvoltage recovery time
AC Performance
Single-ended or differential input and clock mode, 50% clock duty cycle (CLK, CLKB), Binary output data format,
Tj = 70°C, unless otherwise specified.
Signal to Noise and Distortion ratio
–
–
–
–
–
FS = 1 GSPS, FIN = 20 MHz
4
42
44
–
dB
4
41
43
–
dB
4
38
40
–
dB
1, 2, 6
40
44
–
dB
FS = 1 GSPS, FIN = 500 MHz
FS = 1 GSPS, FIN = 1000 MHz (-1 dBFs)
FS = 50 MSPS, FIN = 25 MHz
SINAD
7
2144C–BDC–04/03
Table 3. Electrical Specifications (Continued)
Value
Test
Level
Min
Typ
Max
Unit
–
–
–
–
–
4
7.0
7.2
–
Bits
4
6.6
6.8
–
Bits
4
6.2
6.4
–
Bits
1, 2, 6
7.0
7.2
–
Bits
–
–
–
–
–
4
42
45
–
dB
4
41
44
–
dB
4
41
44
–
dB
1, 2, 6
44
45
–
dB
–
–
–
–
–
4
50
54
–
dB
4
46
50
–
dB
4
42
46
–
dB
1, 2, 6
46
45
–
dB
Spurious Free Dynamic Range
–
–
–
–
–
FS = 1 GSPS, FIN = 20 MHz
4
52
57
–
dBc
4
47
52
–
dBc
FS = 1 GSPS, FIN = 1000 MHz (-1 dBFs)
4
42
47
–
dBc
FS = 1 GSPS, FIN = 1000 MHz (-3 dBFs)
4
45
50
–
dBc
FS = 50 MSPS, FIN = 25 MHz
1, 2, 6
40
54
–
dBc
Two-tone Inter-modulation Distortion
4
–
–
–
–
–
-47
-52
–
dBc
Parameter
Symbol
Effective Number Of Bits
FS = 1 GSPS, FIN = 20 MHz
FS = 1 GSPS, FIN = 500 MHz
ENOB
FS = 1 GSPS, FIN = 1000 MHz (-1 dBFs)
FS = 50 MSPS, FIN = 25 MHz
Signal to Noise Ratio
FS = 1 GSPS, FIN = 20 MHz
FS = 1 GSPS, FIN = 500 MHz
SNR
FS = 1 GSPS, FIN = 1000 MHz (-1 dBFs)
FS = 50 MSPS, FIN = 25 MHz
Total Harmonic Distortion
FS = 1 GSPS, FIN = 20 MHz
FS = 1 GSPS, FIN = 500 MHz
THD
FS = 1 GSPS, FIN = 1000 MHz (-1 dBFs)
FS = 50 MSPS, FIN = 25 MHz
FS = 1 GSPS, FIN = 500 MHz
FIN1 = 489 MHz at FS = 1 GSPS,
FIN2 = 490 MHz at FS = 1 GSPS
Note
(2)
(2)
(2)
SFDR
(2)
IMD
Switching Performance and Charcteristics – See Figure 2 and Figure 3 on page 10
Maximum clock frequency
FS
–
1
–
1.4
GSPS
(14)
Minimum clock frequency
FS
4
10
–
50
MSPS
(15)
Minimum Clock pulse width (high)
TC1
4
0.280
0.500
50
ns
Minimum Clock pulse width (low)
TC2
4
0.350
0.500
50
ns
Ta
4
100
+250
400
ps
(2)
Jitter
4
–
0.4
0.6
ps (rms)
(2)(5)
TDO
4
1150
1360
1660
ps
(11)(12)
Output rise/fall time for DATA (20% – 80%)
TR/TF
4
250
350
550
ps
(11)
Output rise/fall time for DATA READY (20% –
80%)
TR/TF
4
250
350
550
ps
(11)
Aperture delay
Aperture uncertainty
Data output delay
8
(2)(10)
TS8388B
2144C–BDC–04/03
TS8388B
Table 3. Electrical Specifications (Continued)
Parameter
Data ready output delay
Data ready reset delay
Data to data ready – Clock low pulse width
(See “Timing Diagrams” on page 10.)
Data to data ready output delay (50% duty cycle)
at 1 GSPS (See “Timing Diagrams” on page 10.)
Data pipeline delay
Notes:
Value
Symbol
Test
Level
Min
Typ
Max
Unit
Note
TDR
4
1110
1320
1620
ps
(11)(12)
TRDR
4
–
720
1000
ps
TOD-TDR
4
0
40
80
ps
(14)
TD1
4
420
460
500
ps
(2)(15)
TPD
4
(2)(10)
(9)(13)
4
clock
cycles
1.
2.
3.
4.
5.
Differential output buffers are internally loaded by 75Ω resistors. Buffer bias current = 11 mA.
See “Definition of Terms” on page 48.
Histogram testing based on sampling of a 10 MHz sinewave at 50 MSPS.
Output error amplitude < ± 4 lsb around correct code (including gain and offset error).
Maximum jitter value obtained for single-ended clock input on the JTS8388B die (chip on board): 200 fs. (500 fs expected on
TS8388BG)
6. Digital output back termination options depicted in Application Notes.
7. With a typical value of TD = 465 ps, at 1 GSPS, the timing safety margin for the data storing using the ECLinPS 10E452 output registers from Motorola® is of ± 315 ps, equally shared before and after the rising edge of the Data Ready signals (DR,
DRB).
8. The clock inputs may be indifferently entered in differential or single-ended, using ECL levels or 4 dBm typical power level
into the 50Ω termination resistor of the inphase clock input. (4 dBm into 50Ω clock input correspond to 10 dBm power level
for the clock generator.)
9. At 1 GSPS, 50/50 clock duty cycle, TC2 = 500 ps (TC1). TDR - TOD = -100 ps (typ) does not depend on the sampling rate.
10. Specified loading conditions for digital outputs:
- 50Ω or 75Ω controlled impedance traces properly 50/75Ω terminated, or unterminated 75Ω controlled impedance traces.
- Controlled impedance traces far end loaded by 1 standard ECLinPS register from Motorola. (i.e.: 10E452) (Typical input
parasitic capacitance of 1.5 pF including package and ESD protections.)
11. Termination load parasitic capacitance derating values:
- 50Ω or 75Ω controlled impedance traces properly 50/75Ω terminated: 60 ps/pF or 75 ps per additionnal ECLinPS load.
- Unterminated (source terminated) 75Ω controlled impedance lines: 100 ps/pF or 150 ps per additionnal ECLinPS termination load.
12. Apply proper 50/75Ω impedance traces propagation time derating values: 6 ps/mm (155 ps/inch) for TSEV8388B Evaluation
Board.
13. Values for TOD and TDR track each other over temperature, (1% variation for TOD-TDR per 100°C temperature variation).
Therefore TOD-TDR variation over temperature is negligible. Moreover, the internal (on-chip) and package skews between
each Data TODs and TDR effect can be considered as negligible. Consequently, minimum values for TOD and TDR are
never more than 100 ps apart. The same is true for the TOD and TDR maximum values (see Advanced Application Notes
about “TOD-TDR Variation Over Temperature” on page 27).
14. Min value guarantees performance. Max value guarantees functionality.
15. Min value guarantees functionality. Max value guarantees performance.
9
2144C–BDC–04/03
Timing Diagrams
Figure 2. TS8388B Timing Diagram (1 GSPS Clock Rate), Data Ready Reset, Clock Held at LOW Level
TA = 250 ps TBC
X
(VIN, VINB)
X
X
N+1
N
N-1
X
N+2
X
N+3
X
N+5
X
N+4
TC = 1000 ps
TC1
TC2
(CLK, CLKB)
DIGITAL
OUTPUTS
TOD = 1360 ps
TPD: 4.0 Clock periods
1360 ps
DATA
N-5
1000 ps
DATA
N-4
DATA
N-3
DATA
N-2
DATA
N-1
N+1
TD1 = TC1+TDR-TOD
= TC1-40 ps = 460 ps
TDR = 1320 ps
TDR = 1320 ps
DATA
N
Data Ready
(DR, DRB)
TD2 = TC2+TOD-TDR
= TC2+40 ps = 540 ps
TRDR = 720 ps
DRRB
1 ns (min)
Figure 3. TS8388B Timing Diagram (1 GSPS Clock Rate), Data Ready Reset, Clock Held at HIGH Level
TA = 250 ps TBC
X
(VIN, VINB)
N
XN-1
N+1
X
X
X
X
X
N+4
N+2
N+5
TC = 1000 ps
TC1
TC2
(CLK, CLKB)
DIGITAL
OUTPUTS
TOD = 1360 ps
TPD: 4.0 Clock periods
1360 ps
DATA
N-5
1000 ps
DATA
N-4
TDR = 1320 ps
TDR = 1320 ps
DATA
N-3
DATA
N-2
DATA
N-1
DATA
N
DATA
N+1
TD1 = TC1+TDR-TOD
= TC1-40 ps = 460 ps
Data Ready
(DR, DRB)
TRDR = 720 ps
TD2 = TC2+TOD-TDR
= TC2+40 ps = 540 ps
DRRB
1 ns (min)
10
TS8388B
2144C–BDC–04/03
TS8388B
Explanation of
Test Levels
Table 4. Explanation of Test Levels
Num
Characteristics
1
100% production tested at +25°C(1) (for “C” Temperature range(2)).
2
100% production tested at +25°C(1), and sample tested at specified temperatures
(for “V” and “M” Temperature range(2)).
3
Sample tested only at specified temperatures.
4
Parameter is guaranteed by design and characterization testing (thermal steady-state
conditions at specified temperature).
5
Parameter is a typical value only.
6
100% production tested over specified temperature range
(for “B/Q” Temperature range(2)).
Notes:
1. Unless otherwise specified, all tests are pulsed tests: therefore Tj = Tc = Ta, where Tj, Tc
and Ta are junction, case and ambient temperature respectively.
2. Refer to “Ordering Information” on page 50.
3. Only MIN and MAX values are guaranteed (typical values are issuing from characterization
results).
Functions
Description
Table 5. Functions Description
Name
Function
VCC
Positive power supply
VEE
Analog negative power supply
VPLUSD
Digital positive power supply
GND
Ground
VIN, VINB
Differential analog inputs
CLK, CLKB
VCC = +5V
Differential clock inputs
<D0:D7>
<D0B:D7B>
Differential output data port
DR, DRB
Differential data ready outputs
OR, ORB
Out of range outputs
GAIN
ADC gain adjust
GORB
Gray or Binary digital output select
DIOD/DRRB
Die junction temperature measurement/
asynchronous data ready reset
VPLUSD = +0V (ECL)
VPLUSD = +2.4V (LVDS)
VIN
OR
VINB
ORB
CLK
CLKB
TS8388B
16
GAIN
D0
D0B
D7
D7B
DR
GORG
DRB
DIOD/
DRRB
DVEE = -5V
VEE = -5V
GND
11
2144C–BDC–04/03
Digital Output
Coding
NRZ (Non Return to Zero) mode, ideal coding: does not include gain, offset, and linearity voltage errors.
Table 6. Digital Output Coding
Digital Output
Voltage Level
Binary
GORB = VCC or Floating
Gray
GORB = GND
Out of
Range
> +251 mV
> Positive full scale + 1/2 lsb
11111111
10000000
1
+251 mV
+249 mV
Positive full scale + 1/2 lsb
Positive full scale - 1/2 lsb
11111111
11111110
10000000
10000001
0
0
+126 mV
+124 mV
Positive 1/2 scale + 1/2 lsb
Positive 1/2 scale - 1/2 lsb
11000000
10111111
10100000
11100000
0
0
+1 mV
-1 mV
Bipolar zero + 1/2 lsb
Bipolar zero - 1/2 lsb
10000000
01111111
11000000
01000000
0
0
-124 mV
-126 mV
Negative 1/2 scale + 1/2 lsb
Negative 1/2 scale - 1/2 lsb
01000000
00111111
01100000
00100000
0
0
-249 mV
-251 mV
Negative full scale + 1/2 lsb
Negative full scale - 1/2 lsb
00000001
00000000
00000001
00000000
0
0
< -251 mV
< Negative full scale - 1/2 lsb
00000000
00000000
1
Differential
Analog Input
12
TS8388B
2144C–BDC–04/03
TS8388B
Package
Description
Pin Description
Table 7. TS8388BGL Pin Description (CBGA68 package)
Symbol
Pin number
Function
GND
A2, A5, B1, B5, B10, C2, D2, E1, E2, E11,
F1, F2, G11, K2, K3, K4, K5, K10, L2, L5
Ground pins.
To be connected to external ground plane.
VCC
A4, A6, B2, B4, B6, H1, H2, L6, L7
+5V positive supply.
VEE
A3, B3, G1, G2, J1, J2
5V analog negative supply.
DVEE
F10, F11
-5V digital negative supply.
VIN
L3
In phase (+) analog input signal of the Sample and Hold
differential preamplifier.
VINB
L4
Inverted phase (-) of ECL clock input signal (CLK).
CLK
C1
In phase (+) ECL clock input signal. The analog input is
sampled and held on the rising edge of the CLK signal.
CLKB
D1
Inverted phase (-) of ECL clock input signal (CLK).
B0, B1, B2, B3, B4,
B5, B6, B7
A8, A9, A10, D10, H11, J11, K9, K8
In phase (+) digital outputs.
B0 is the LSB. B7 is the MSB.
B0B, B1B, B2B, B3B,
B4B, B5B, B6B, B7B
B7, B8, B9, C11, G10, H10, L10, L9
Inverted phase (-) digital outputs.
B0B is the inverted LSB. B7B is the inverted MSB.
OR
K7
In phase (+) Out of Range Bit. Out of Range is high on the
leading edge of code 0 and code 256.
ORB
L8
Inverted phase (+) Out of Range Bit (OR).
DR
E10
In phase (+) output of Data Ready Signal.
DRB
D11
Inverted phase (-) output of Data Ready Signal (DR).
GORB
A7
Gray or Binary select output format control pin.
- Binary output format if GORB is floating or VCC.
- Gray output format if GORB is connected at ground (0V).
GAIN
K6
ADC gain adjust pin. The gain pin is by default grounded, the
ADC gain transfer fuction is nominally close to one.
DIOD/DRRB
K1
Die function temperature measurement pin and
asynchronous data ready reset active low, single-ended ECL
input.
VPLUSD
B11, C10, J10, K11
+2.4V for LVDS output levels otherwise to GND(2).
NC
A1, A11, L1, L11
Not connected.
Note:
1. The common mode level of the output buffers is 1.2V below the positive digital supply.
For ECL compatibility the positive digital supply must be set at 0V (ground).
For LVDS compatibility (output common mode at +1.2V) the positive digital supply must be set at 2.4V.
If the subsequent LVDS circuitry can withstand a lower level for input common mode, it is recommended to lower the positive digital supply level in the same proportion in order to spare power dissipation.
13
2144C–BDC–04/03
TS8388BGL Pinout
Figure 4. TS8388BGL Pinout of CBGA 68 Package
11
NC
VPLUSD
B3b
DRb
GND
DVEE
GND
B4
B5
VPLUSD
NC
10
B2
GND
VPLUSD
B3
DR
DVEE
B4b
B5b
VPLUSD
GND
B6b
9
B1
B2b
B6
B7b
8
B0
B1b
B7
ORb
7
Gorb
B0b
OR
VCC
6
VCC
VCC
GAIN
VCC
5
GND
GND
GND
GND
4
VCC
VCC
GND
VINB
3
VEE
VEE
GND
VIN
2
GND
VCC
GND
GND
GND
GND
VEE
VCC
VEE
GND
GND
1
NC
GND
CLK
CLKB
GND
GND
VEE
VCC
VEE
Diode
NC
A
B
C
D
E
F
G
H
K
L
Ball
A1 Index
other side
J
BOTTOM VIEW
14
TS8388B
2144C–BDC–04/03
TS8388B
Table 8. TS8388BF/TS8388BFS Pin Description (CQFP68 package)
Symbol
Pin number
Function
GND
5, 13, 27, 28, 34, 35, 36, 41, 42, 43, 50, 51,
52, 53, 58, 59
Ground pins.
To be connected to external ground plane.
VPLUSD
1, 2, 16, 17, 18, 68
Digital positive supply (0V for ECL compatibility, 2.4V for
LVDS compatibility).(2)
VCC
26, 29, 32, 33, 46, 47, 61
+5V positive supply.
VEE
30, 31, 44, 45, 48
-5V analog negative supply.
DVEE
8, 9, 10
-5V digital negative supply.
VIN
54(1), 55
In phase (+) analog input signal of the Sample and Hold
differential preamplifier.
VINB
56, 57(1)
Inverted phase (-) of analog input signal (VIN).
CLK
37(1), 38
In phase (+) ECL clock input signal. The analog input is
sampled and held on the rising edge of the CLK signal.
CLKB
39, 40(1)
Inverted phase (-) of ECL clock input signal (CLK).
D0, D1, D2, D3, D4,
D5, D6, D7
23, 21, 19, 14, 6, 3, 66, 64
In phase (+) digital outputs.
B0 is the LSB. B7 is the MSB.
D0B, D1B, D2B, D3B,
D4B, D5B, D6B, D7B
24, 22, 20, 15, 7, 4, 67, 65
Inverted phase (-) digital outputs.
B0B is the inverted LSB. B7B is the inverted MSB.
OR
62
In phase (+) Out of Range Bit. Out of Range is high on the
leading edge of code 0 and code 256.
ORB
63
Inverted phase (+) Out of Range Bit (OR).
DR
11
In phase (+) output of Data Ready Signal.
DRB
12
Inverted phase (-) output of Data Ready Signal (DR).
GORB
25
Gray or Binary select output format control pin.
- Binary output format if GORB is floating or VCC.
- Gray output format if GORB is connected at ground (0V).
GAIN
60
ADC gain adjust pin.
DIOD/DRRB
49
This pin has a double function (can be left open or grounded
if not used):
- DIOD: die junction temperature monitoring pin.
- DRRB: asynchronous data ready reset function.
Notes:
1. Following pin numbers 37 (CLK), 40 (CLKB), 54 (VIN) and 57 (VINB) have to be connected to GND through a 50Ω resistor as
close as possible to the package (50Ω termination preferred option).
2. The common mode level of the output buffers is 1.2V below the positive digital supply.
For ECL compatibility the positive digital supply must be set at 0V (ground).
For LVDS compatibility (output common mode at +1.2V) the positive digital supply must be set at 2.4V.
If the subsequent LVDS circuitry can withstand a lower level for input common mode, it is recommended to lower the positive digital supply level in the same proportion in order to spare power dissipation.
15
2144C–BDC–04/03
TS8388BF/
TS8388BFS Pinout
Figure 5. TS8388BF/TS8388BFS Pinout of CQFP68 package
9
8
7
6
5
4
3
2
1
DVEE
D4B
D4
GND
D5B
D5
VPLUSD
VPLUSD
DVEE
DR
DRB
GND
D3
VPLUSD
D3B
VPLUSD
17 16 15 14 13 12 11 10
DVEE
TOP VIEW
Pin 1 index
18 VPLUSD
VPLUSD 68
19
D2
D6B
67
20
D2B
D6
66
D7B
65
D7
64
ORB
63
OR
62
VCC
61
Gain
60
21
D1
22
D1B
23
D0
24
D0B
25
GORB
26
VCC
27
GND
GND
59
28
GND
GND
58
29
VCC
VINb
57
30
VEE
VINb
56
31
VEE
VIN
55
32
VCC
VIN
54
33
VCC
GND
53
34
GND
GND
52
GND
GND
Diode
VEE
VCC
VCC
VEE
VEE
GND
GND
GND
CLKb
CLKb
CLK
CLK
GND
GND
TS8388BF/TS8388BFS
35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51
16
TS8388B
2144C–BDC–04/03
TS8388B
Typical
Characterization
Results
Static Linearity
FS = 50 MSPS/FIN = 10 MHz
Figure 6. Integral Non Linearity
Note:
Clock Frequency = 50 MSPS; Signal Frequency = 10 MHz;
Positive peak: 0.78 lsb; Negative peak: -0.73 lsb
Figure 7. Differential Non Linearity
Note:
Clock Frequency = 50 MSPS; Signal Frequency = 10 MHz;
Positive peak: 0.3 lsb; Negative peak: -0.39 lsb
17
2144C–BDC–04/03
Effective Number
of Bits Versus
Power Supplies
Variation
Figure 8. Effective Number of Bits = f (VEEA); FS = 500 MSPS; FIN = 100 MHz
8
7
ENOB (bits)
6
5
4
3
2
1
0
-7
-6.5
-6
-5.5
-5
-4.5
-4
VEEA (V)
Figure 9. Effective Number of Bits = f (VCC); FS = 500 MSPS; FIN = 100 MHz
8
7
ENOB (bits)
6
5
4
3
2
1
0
3
3.5
4
4.5
5
5.5
6
6.5
7
VCC (V)
Figure 10. Effective Number of Bits = f (VEED); FS = 500 MSPS; FIN = 100 MHz
8
7
ENOB (bits)
6
5
4
3
2
1
0
-6
-5.5
-5
-4.5
-4
-3.5
-3
VEED (V)
18
TS8388B
2144C–BDC–04/03
TS8388B
Typical FFT Results
Figure 11. FS = 1 GSPS; FIN = 20 MHz
Figure 12. FS = 1 GSPS; FIN = 495 MHz
Figure 13. FS = 1 GSPS; FIN = 995 MHz (-3 dB Full Scale Input)
19
2144C–BDC–04/03
Spurious Free
Dynamic Range
Versus Input
Amplitude
Figure 14. Sampling Frequency: FS = 1 GSPS; Input Frequency FIN = 995 MHz; Full Scale; ENOB = 6.4;
SINAD = 40 dB; SNR = 44 dB; THD = -46 dBc; SFDR = -47 dBc; Gray or Binary Output Coding
Figure 15. Sampling Frequency: FS = 1 GSPS; Input Frequency FIN = 995 MHz; -3 dB Full Scale; ENOB = 6.6;
SINAD = 40.8 dB; SNR = 44 dB; THD = -48 dBc; SFDR = -50 dBc; Gray or Binary Output Coding
20
TS8388B
2144C–BDC–04/03
TS8388B
Dynamic
Performance
Versus Analog
Input Frequency
FS = 1 GSPS, FIN = 0 up to 1600 MHz, Full Scale input (FS), FS -3 dB
Clock duty cycle 50/50, Binary/Gray output coding, fully differential or single-ended analog and
clock inputs.
Figure 16. ENOB (dB)
8
ENOB (dB)
7
-3 dB FS
6
5
FS
4
3
0
200
400
600
800
1000
1200
1400
1600
1800
Input frequency (MHz)
Figure 17. SNR (dB)
50
48
46
SNR (dB)
44
FS
42
40
-3 dB FS
38
36
34
32
30
0
200
400
600
800
1000
Input frequency (MHz)
1200
1400
1600
1800
Figure 18. SFDR (dBc)
-20
-25
SFDR (dBc)
-30
FS
-35
-40
-3 dB FS
-45
-50
-55
-60
0
200
400
600
800
1000
1200
1400
1600
1800
Input frequency (MHz)
21
2144C–BDC–04/03
Effective Number
of Bits (ENOB)
Versus Sampling
Frequency
Analog Input Frequency: FIN = 495 MHz and Nyquist conditions (FIN = FS/2)
Clock duty cycle 50/50, Binary output coding
Figure 19. ENOB (dB)
8
FIN = FS/2
7
FIN = 500 MHz
ENOB (dB)
6
5
4
3
2
0
200
400
600
800
1000
1200
1400
1600
Sampling frequency (MSPS)
SFDR Versus
Sampling
Frequency
Analog Input Frequency: FIN = 495 MHz and Nyquist conditions (FIN = FS/2)
Clock duty cycle 50/50, Binary output coding
Figure 20. SFDR (dBc)
-20
-25
-30
SFDR (dBc)
-35
-40
-45
FIN = FS/2
-50
FIN = 500 MHz
-55
-60
0
200
400
600
800
1000
1200
1400
1600
Sampling frequency (MSPS)
22
TS8388B
2144C–BDC–04/03
TS8388B
TS8388B ADC
Performances
Versus Junction
Temperature
Figure 21. Effective Number of Bits Versus Junction Temperature
FS = 1 GSPS; FIN = 500 MHz; Duty Cycle = 50%
8
ENOB (bits)
7
6
5
4
3
-40
-20
0
20
40
60
80
Temperature (°C)
100
120
140
160
Figure 22. Signal to Noise Ratio Versus Junction Temperature
FS = 1 GSPS; FIN = 507 MHz; Differential Clock; Single-ended Analog Input (VIN = -1 dBFs)
46
SNR (dB)
45
44
43
42
-60
-40
-20
0
20
40
Temperature (°C)
60
80
100
120
Figure 23. Total Harmonic Distorsion Versus Junction Temperature
FS = 1 GSPS; FIN = 507 MHz; Differential Clock; Single-ended Analog Input (VIN = -1 dBFs)
53
THD (dB)
51
49
47
45
43
-60
-40
-20
0
20
40
Temperature (°C)
60
80
100
120
23
2144C–BDC–04/03
Figure 24. Power Consumption Versus Junction Temperature
FS = 1 GSPS; FIN = 500 MHz; Duty Cycle = 50%
5
Power consumption (W)
4
3
2
1
0
-40
-20
0
20
40
60
80
100
120
140
160
Temperature (°C)
Typical Full Power
Input Bandwidth
Figure 25. 1.8 GHz at -3 dB (-2 dBm Full Power Input) – CBGA68 package
Frequency (MHz)
400
600
800
1000
1200
1400
1600
1800
2000
0
Magnitude (dB)
-1
-2
-3
-4
-5
-6
24
TS8388B
2144C–BDC–04/03
TS8388B
Figure 26. 1.5 GHz at -3 dB (-2 dBm Full Power Input) – CQFP68 package
Frequency (MHz)
100
300
500
700
900
1100
1300
1500
1700
0
-1
Magnitude (dB)
-2
-3
-4
-5
-6
25
2144C–BDC–04/03
ADC Step
Response
Test pulse input characteristics: 20% to 80% input full scale and rise time ~ 200 ps.
Note:
This step response was obtained with the TSEV8388B chip on-board (device in die form).
Figure 27. Test Pulse Digitized with 20 GHz DSO
Vpp ~ 260 mV
Tr ~ 240 ps
50 mV/div
500 ps/div
0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
4.5
5.0
Time (ns)
Figure 28. Same Test Pulse Digitized with TS8388B ADC
200
ADC code
150
Tr ~ 280 ps
50 codes/div (Vpp ~ 260 mV)
100
500 ps/div
ADC calculated rise time: between 150 and 200 ps
50
0
0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
4.5
5.0
Time (ns)
Note:
26
Ripples are due to the test setup (they are present on both measurements).
TS8388B
2144C–BDC–04/03
TS8388B
TS8388B Main
Features
Timing
Information
Timing Value for
TS8388B
Timing values as defined in Table 3 on page 4 are advanced data, issued from electric simulations and first characterizations results fitted with measurements.
Timing values are given at package inputs/outputs, taking into account package internal controlled impedance traces propagation delays, gullwing pin model, and specified termination
loads.
Propagation delays in 50/75Ω impedance traces are NOT taken into account for TOD and
TDR.
Apply proper derating values corresponding to termination topology.
The min/max timing values are valid over the full temperature range in the following
conditions:
Propagation Time
Considerations
•
Specified Termination Load (Differential output Data and Data Ready):
50Ω resistor in parallel with 1 standard ECLinPS register from Motorola (i.e.: 10E452)
Typical ECLinPS inputs shows a typical input capacitance of 1.5 pF (including package
and ESD protections).
If addressing an output Dmux, take care if some Digital outputs do not have the same
termination load and apply corresponding derating value given below.
•
Output Termination Load derating values for TOD and TDR:
~ 35 ps/pF or 50 ps per additional ECLinPS load.
•
Propagation time delay derating values have also to be applied for TOD and TDR:
~ 6 ps/mm (155 ps/inch) for TSEV8388B Evaluation Board.
Apply proper time delay derating value if a different dielectric layer is used.
TOD and TDR Timing values are given from pin to pin and DO NOT include the additional
propagation times between device pins and input/output termination loads. For the
TSEV8388B Evaluation Board, the propagation time delay is 6 ps/mm (155 ps/inch) corresponding to 3.4 (at 10 GHz) dielectric constant of the RO4003 used for the Board.
If a different dielectric layer is used (for instance Teflon), please use appropriate propagation
time values.
TD does NOT depend on propagation times because it is a differential data (TD is the time difference between Data Ready output delay and digital Data output delay).
TD is also the most straightforward data to measure, again because it is differential: TD can be
measured directly onto termination loads, with matched Oscilloscopes probes.
TOD-TDR Variation
Over Temperature
Values for TOD and TDR track each other over temperature (1% variation for TOD-TDR per
100°C temperature variation).
Therefore TOD-TDR variation over temperature is negligible. Moreover, the internal (on-chip)
and package skews between each Data TODs and TDR effect can be considered as
negligible.
27
2144C–BDC–04/03
Consequently, minimum values for TOD and TDR are never more than 100 ps apart. The
same is true for the TOD and TDR maximum values.
In other terms :
–
If TOD is at 1150 ps, TDR will not be at 1620 ps (maximum time delay for TDR).
–
If TOD is at 1660 ps, TDR will not be at 1110 ps (minimum time delay for TDR).
However, external TOD-TDR values may be dictated by total digital datas skews
between every TODs (each digital data) and TDR: MCM Board, bonding wires and
output lines lengths differences, and output termination impedance mismatches.
The external (on board) skew effect has NOT been taken into account for the specification of
the minimum and maximum values for TOD-TDR.
Principle of Operation
The Analog input is sampled on the rising edge of external clock input (CLK, CLKB) after TA
(aperture delay) of typically 250 ps. The digitized data is available after 4 clock periods latency
(pipeline delay (TPD)), on clock rising edge, after 1360 ps typical propagation delay TOD.
The Data Ready differential output signal frequency (DR, DRB) is half the external clock frequency, that is it switches at the same rate as the digital outputs.
The Data Ready output signal (DR, DRB) switches on external clock falling edge after a propagation delay TDR of typically 1320 ps.
A Master Asynchronous Reset input command DRRB (ECL compatible single-ended input) is
available for initializing the differential Data Ready output signal (DR, DRB). This feature is
mandatory in certain applications using interleaved ADCs or using a single ADC with demultiplexed outputs. Actually, without Data Ready signal initialization, it is impossible to store the
output digital datas in a defined order.
Principle of Data
Ready Signal
Control by DRRB
Input Command
Data Ready Output
Signal Reset
The Data Ready signal is reset on falling edge of DRRB input command, on ECL logical low
level (-1.8V). DRRB may also be tied to VEE = -5V for Data Ready output signal Master Reset.
So long DRRB remains at logical low level, (or tied to VEE = -5V), the Data Ready output
remains at logical zero and is independant of the external free running encoding clock.
The Data Ready output signal (DR, DRB) is reset to logical zero after TRDR = 920 ps typical.
TRDR is measured between the -1.3V point of the falling edge of DRRB input command and
the zero crossing point of the differential Data Ready output signal (DR, DRB).
The Data Ready Reset command may be a pulse of 1 ns minimum time width.
28
TS8388B
2144C–BDC–04/03
TS8388B
Data Ready Output
Signal Restart
The Data Ready output signal restarts on DRRB command rising edge, ECL logical high levels
(-0.8V). DRRB may also be Grounded, or is allowed to float, for normal free running Data
Ready output signal.
The Data Ready signal restart sequence depends on the logical level of the external encoding
clock, at DRRB rising edge instant:
•
The DRRB rising edge occurs when external encoding clock input (CLK, CLKB) is LOW:
The Data Ready output first rising edge occurs after half a clock period on the clock falling
edge, after a delay time TDR = 1320 ps already defined hereabove.
•
The DRRB rising edge occurs when external encoding clock input (CLK, CLKB) is HIGH:
The Data Ready output first rising edge occurs after one clock period on the clock falling
edge, and a delay TDR = 1320 ps.
Consequently, as the analog input is sampled on clock rising edge, the first digitized data corresponding to the first acquisition (N) after Data Ready signal restart (rising edge) is always
strobed by the third rising edge of the data ready signal.
The time delay (TD1) is specified between the last point of a change in the differential output
data (zero crossing point) to the rising or falling edge of the differential Data Ready signal (DR,
DRB) (zero crossing point).
For normal initialization of Data Ready output signal, the external encoding clock signal frequency and level must be controlled. It is reminded that the minimum encoding clock sampling
rate for the ADC is 10 MSPS and consequently the clock cannot be stopped.
One single pin is used for both DRRB input command and die junction temperature monitoring. Pin denomination will be DRRB/DIOD. On the former version denomination was DIOD.
Temperature monitoring and Data Ready control by DRRB is not possible simultaneously.
Analog Inputs (VIN)
(VINB)
The analog input Full Scale range is 0.5V peak to peak (Vpp), or -2 dBm into the 50Ω termination resistor.
In differential mode input configuration, that means 0.25V on each input, or ±125 mV around
0V. The input common mode is GROUND.
The typical input capacitance is 3 pF for TS8388B in CQFP and CBGA packages.
The input capacitance is mainly due to the package. The ESD protections are not connected
(but present) on the inputs.
Differential Inputs
Voltage Span
Figure 29. Differential Inputs Voltage Span
[mV]
VIN
125
500 mV
Full Scale
analog input
250 mV
VINB
-250 mV
-125
0V
t
(VIN, VINB) = ±250 mV = 500 mV diff
29
2144C–BDC–04/03
Differential Versus
Single-ended Analog
Input Operation
The TS8388B can operate at full speed in either differential or single-ended configuration.
This is explained by the fact the ADC uses a high input impedance differential preamplifier
stage, (preceeding the Sample and hold stage), which has been designed in order to be
entered either in differential mode or single-ended mode.
This is true so long as the out-of-phase analog input pin VINB is 50Ω terminated very closely to
one of the neighboring shield ground pins (52, 53, 58, 59) which constitute the local ground
reference for the inphase analog input pin (VIN).
Thus the differential analog input preamplifier will fully reject the local ground noise (and any
capacitively and inductively coupled noise) as common mode effects.
In typical single-ended configuration, enter on the (VIN) input pin, with the inverted phase input
pin (VINB) grounded through the 50Ω termination resistor.
In single-ended input configuration, the in-phase input amplitude is 0.5V peak to peak, centered on 0V (or -2 dBm into 50Ω). The inverted phase input is at ground potential through a
50Ω termination resistor.
However, dynamic performances can be somewhat improved by entering either analog or
clock inputs in differential mode.
Typical Single-ended
Analog Input
Configuration
Figure 30. Typical Single-ended Analog Input Configuration
[mV]
VIN or VINB double pad (pins 54, 55 or 56, 57)
VIN
250
500 mV
Full Scale
analog input
VIN or VINB
500 mV
VINB = 0V
VINB
-250
1 MΩ
3 pF
t
VIN = ±250 mV = 500 mV diff
Note:
50Ω
(external or
on package)
50Ω reverse termination
Since VIN and VINB have a double pad architecture, a 50Ω reverse termination is needed. For the CBGA package, this reverse
termination is already on package.
Clock Inputs (CLK)
(CLKB)
The TS8388B can be clocked at full speed without noticeable performance degradation in
either differential or single-ended configuration.
This is explained by the fact the ADC uses a differential preamplifier stage for the clock buffer,
which has been designed in order to be entered either in differential or single-ended mode.
Recommended sinewave generator characteristics are typically -120 dBc/Hz phase noise floor
spectral density, at 1 kHz from carrier, assuming a single tone 4 dBm input for the clock signal.
Single-ended Clock
Input (Ground
Common Mode)
30
Although the clock inputs were intended to be driven differentially with nominal -0.8V/-1.8V
ECL levels, the TS8388B clock buffer can manage a single-ended sinewave clock signal centered around 0V. This is the most convenient clock input configuration as it does not require
the use of a power splitter.
TS8388B
2144C–BDC–04/03
TS8388B
No performance degradation (i.e.: due to timing jitter) is observed in this particular singleended configuration up to 1.2 GSPS Nyquist conditions (FIN = 600 MHz).
This is true so long as the inverted phase clock input pin is 50Ω terminated very closely to one
of the neighboring shield ground pins, which constitutes the local Ground reference for the
inphase clock input.
Thus the TS8388B differential clock input buffer will fully reject the local ground noise (and any
capacitively and inductively coupled noise) as common mode effects. Moreover, a very low
phase noise sinewave generator must be used for enhanced jitter performance.
The typical inphase clock input amplitude is 1V peak to peak, centered on 0V (ground) common mode. This corresponds to a typical clock input power level of 4 dBm into the 50Ω
termination resistor. Do not exceed 10 dBm to avoid saturation of the preamplifier input
transistors.
The inverted phase clock input is grounded through the 50Ω termination resistor.
Figure 31. Single-ended Clock Input (Ground common mode):
VCLK Common Mode = 0V; VCLKB = 0V; 4 dBm Typical Clock Input Power Level (into 50Ω termination resistor)
CLK or CLKB double pad (pins 37, 38 or 39, 40)
[V]
VCLK
+0.5V
CLK or CLKB
VCLK = 0V
VCLK
-0.5V
1 MΩ
50Ω
(external or
on package)
t
Note:
Differential ECL Clock
Input
0.4 pF
50Ω reverse termination
Do not exceed 10 dBm into the 50Ω termination resistor for single clock input power level.
The clock inputs can be driven differentially with nominal -0.8V/-1.8V ECL levels.
In this mode, a low phase noise sinewave generator can be used to drive the clock inputs, followed by a power splitter (hybrid junction) in order to obtain 180 degrees out of phase
sinewave signals. Biasing tees can be used for offseting the common mode voltage to ECL
levels.
Note: As the biasing tees propagation times are not matching, a tunable delay line is required
in order to ensure the signals to be 180 degrees out of phase especially at fast clock rates in
the GSPS range.
Figure 32. Differential Clock Inputs (ECL Levels)
[mV]
-0.8V
CLK or CLKB double pad (pins 37, 38 or 39, 40)
VCLK
VCLKB
CLK or CLKB
Common mode = -1.3V
-1.8V
t
50Ω
(external or
on package)
1 MΩ
0.4 pF
-2V
50Ω reverse termination
31
2144C–BDC–04/03
Single-ended ECL
Clock Input
In single-ended configuration enter on CLK (resp. CLKB) pin, with the inverted phase Clock
input pin CLKB (respectively CLK) connected to -1.3V through the 50Ω termination resistor.
The inphase input amplitude is 1V peak to peak, centered on -1.3V common mode.
Figure 33. Single-ended Clocl Input (ECL):
VCLK Common Mode = -1.3V; VCLKB = -1.3V
[V]
-0.8V
VCLK
VCLKB = -1.3V
-1.8V
Noise Immunity
Information
t
Circuit noise immunity performance begins at design level.
Efforts have been made on the design in order to make the device as insensitive as possible
to chip environment perturbations resulting from the circuit itself or induced by external circuitry (Cascode stages isolation, internal damping resistors, clamps, internal (on-chip)
decoupling capacitors).
Furthermore, the fully differential operation from analog input up to the digital outputs provides
enhanced noise immunity by common mode noise rejection.
Common mode noise voltage induced on the differential analog and clock inputs will be canceled out by these balanced differential amplifiers.
Moreover, proper active signals shielding has been provided on the chip to reduce the amount
of coupled noise on the active inputs.
The analog inputs and clock inputs of the TS8388B device have been surrounded by ground
pins, which must be directly connected to the external ground plane.
Digital Outputs
The TS8388B differential output buffers are internally 75Ω loaded. The 75Ω resistors are connected to the digital ground pins through a -0.8V level shift diode (see Figure 34, Figure 35,
Figure 36 on page 35).
The TS8388B output buffers are designed for driving 75Ω (default) or 50Ω properly terminated
impedance lines or coaxial cables. An 11 mA bias current flowing alternately into one of the
75Ω resistors when switching ensures a 0.825V voltage drop across the resistor (unterminated outputs).
The VPLUSD positive supply voltage allows the adjustment of the output common mode level
from -1.2V (VPLUSD = 0V for ECL output compatibility) to +1.2V (VPLUSD = 2.4V for LVDS output
compatibility).
Therefore, the single-ended output voltages vary approximately between -0.8V and -1.625V,
(outputs unterminated), around -1.2V common mode voltage.
32
TS8388B
2144C–BDC–04/03
TS8388B
Three possible line driving and back-termination scenarios are proposed (assuming VPLUSD =
0V):
1. 75Ω impedance transmission lines, 75Ω differentially terminated (Figure 34):
Each output voltage varies between -1V and -1.42V (respectively +1.4V and +1V), leading
to ±0.41V = 0.825V in differential, around -1.21V (respectively +1.21V) common mode for
VPLUSD = 0V (respectively 2.4V).
2. 50Ω impedance transmission lines, 50Ω differentially termination (Figure 35):
Each output voltage varies between -1.02V and -1.35V (respectively +1.38V and +1.05V),
leading to ±0.33V = 660 mV in differential, around -1.18V (respectively +1.21V) common
mode for VPLUSD = 0V (respectively 2.4V).
3. 75Ω impedance open transmission lines (Figure 36):
Each output voltage varies between -1.6V and -0.8V (respectively +0.8V and +1.6V),
which are true ECL levels, leading to ±0.8V = 1.6V in differential, around -1.2V (respectively +1.2V) common mode for VPLUSD = 0V (respectively 2.4V). Therefore, it is possible
to drive directly high input impedance storing registers, without terminating the 75Ω transmission lines. In time domain, that means that the incident wave will reflect at the 75Ω
transmission line output and travel back to the generator (i.e.: the 75Ω data output buffer).
As the buffer output impedance is 75Ω, no back reflection will occur.
Note: This is no longer true if a 50Ω transmission line is used, as the latter is not matching the
buffer 75Ω output impedance.
Each differential output termination length must be kept identical. It is recommended to decouple the midpoint of the differential termination with a 10 nF capacitor to avoid common mode
perturbation in case of slight mismatch in the differential output line lengths.
Too large mismatches (keep < a few mm) in the differential line lengths will lead to switching
currents flowing into the decoupling capacitor leading to switching ground noise.
The differential output voltage levels (75Ω or 50Ω termination) are not ECL standard voltage
levels, however it is possible to drive standard logic ECL circuitry like the ECLinPS logic line
from Motorola®.
At sampling rates exceeding 1 GSPS, it may be difficult to trigger any Acquisition System with
digital outputs. It becomes necessary to regenerate digital data and Data Ready by means of
external amplifiers, in order to be able to test the TS8388B at its optimum performance
conditions.
33
2144C–BDC–04/03
Differential Output Loading Configurations (Levels for ECL Compatibility)
Figure 34. Differential Output: 75Ω Terminated
VPLUSD = 0V
-0.8V
Out
75Ω
75Ω
-1V/-1.41V
75Ω
Differential output:
+0.41V = 0.825V
75Ω
+
-
75Ω
impedance
10 nF
Common mode level: -1.2V
(-1.2V below VPLUSD level)
75Ω
OutB
-1.41V/-1V
Out
-1.02V/-1.35V
11 mA
DVEE
Figure 35. Differential Output: 50Ω Terminated
VPLUSD = 0V
-0.8V
75Ω
75Ω
50Ω
50Ω
+
-
50Ω
impedance
10 nF
50Ω
Differential output:
+0.33V = 0.660V
Common mode level: -1.2V
(-1.2V below VPLUSD level)
OutB
-1.35V/-1.02V
11 mA
DVEE
34
TS8388B
2144C–BDC–04/03
TS8388B
Figure 36. Differential Output: Open Loaded
VPLUSD = 0V
-0.8V
Out
75Ω
75Ω
Differential output:
+0.8V = 1.6V
75Ω
+
-
-0.8V/-1.6V
Common mode level: -1.2V
(-1.2V below VPLUSD level)
75Ω
impedance
OutB
-1.6V/-0.8V
Out
1.4V/0.99V
11 mA
DVEE
Differential Output Loading Configurations (Levels for LVDS Compatibility)
Figure 37. Differential Output: 75Ω Terminated
VPLUSD = 2.4V
1.6V
75Ω
75Ω
75Ω
75Ω
+
-
75Ω
impedance
10 nF
75Ω
Differential output:
+0.41V = 0.825V
Common mode level: -1.2V
(-1.2V below VPLUSD level)
OutB
0.99V/1.4V
11 mA
DVEE
35
2144C–BDC–04/03
Figure 38. Differential Output: 50Ω Terminated
VPLUSD = 2.4V
1.6V
1.38V/1.05V
Out
75Ω
75Ω
50Ω
Differential output:
+0.33V = 0.660V
50Ω
+
-
50Ω
impedance
10 nF
Common mode level: -1.2V
(-1.2V below VPLUSD level)
50Ω
OutB
1.05V/1.38V
Out
1.6V/0.8V
11 mA
DVEE
Figure 39. Differential Output: Open Loaded
VPLUSD = 2.4V
1.6V
75Ω
75Ω
75Ω
+
-
75Ω
impedance
Differential output:
+0.8V = 1.6V
Common mode level: -1.2V
(-1.2V below VPLUSD level)
OutB
0.8V/1.6V
11 mA
DVEE
Out of Range Bit
An Out of Range (OR, ORB) bit is provided that goes to logical high state when the input
exceeds the positive full scale or falls below the negative full scale.
When the analog input exceeds the positive full scale, the digital output datas remain at high
logical state, with (OR, ORB) at logical one.
When the analog input falls below the negative full scale, the digital outputs remain at logical
low state, with (OR, ORB) at logical one again.
Gray or Binary
Output Data
Format Select
The TS8388B internal regeneration latches indecision (for inputs very close to latches threshold) may produce errors in the logic encoding circuitry and leading to large amplitude output
errors.
This is due to the fact that the latches are regenerating the internal analog residues into logical
states with a finite voltage gain value (Av) within a given positive amount of time ∆(t):
Av = exp(∆(t)/τ), with τ the positive feedback regeneration time constant.
The TS8388B has been designed for reducing the probability of occurrence of such errors to
approximately 10-13 (targeted for the TS8388B at 1 GSPS).
36
TS8388B
2144C–BDC–04/03
TS8388B
A standard technique for reducing the amplitude of such errors down to ± 1 lsb consists of outputting the digital datas in Gray code format. Though the TS8388B has been designed for
featuring a Bit Error Rate of 10-13 with a binary output format, it is possible for the user to
select between the Binary or Gray output data format, in order to reduce the amplitude of such
errors when occurring, by storing Gray output codes.
Digital Datas format selection:
Diode Pin 49
•
BINARY output format if GORB is floating or VCC.
•
GRAY output format if GORB is connected to ground (0V).
One single pin is used for both DRRB input command and die junction monitoring. The pin
denomination is DRRB/DIOD. Temperature monitoring and Data Ready control by DRRB is
not possible simultaneously.
(See “Principle of Data Ready Signal Control by DRRB Input Command” on page 28 for Data
Ready Reset input command).
The operating die junction temperature must be kept below 145°C, therefore an adequate
cooling system has to be set up. The diode mounted transistor measured Vbe value versus
junction temperature is given below.
Figure 40. Diode Pin 49
1000
960
920
VBE (mV)
880
840
800
760
720
680
640
600
-55
ADC Gain Control
Pin 60
-35
-15
5
25
45
65
Junction temperature (°C)
85
105
125
The ADC gain is adjustable by the means of the pin 60 (input impedance is 1 MΩ in parallel
with 2 pF).
The gain adjust transfer function is given below.
37
2144C–BDC–04/03
Figure 41. ADC Gain Control Pin 60
1.20
1.15
ADC Gain
1.10
1.05
1.00
0.95
0.90
0.85
0.80
-500
-400
-300
-200
-100
0
100
200
300
400
500
Vgain (command voltage) (mV)
Note:
38
For more information, please refer to the document "DEMUX and ADCs Application Notes".
TS8388B
2144C–BDC–04/03
TS8388B
Equivalent
Input/Output
Schematics
Figure 42. Equivalent Analog Input Circuit and ESD Protections
VCC = +5V
VCC
VCLAMP = +2.4V
-0.8V
-0.8V
GND
GND = 0V
-5.8V
-5.8V
+1.65V
50Ω
50Ω
E21V
E21V
VEE
VEE
200Ω
200Ω
VIN
VINB
Pad
capacitance
340 fF
Pad
capacitance
340 fF
5.8V
5.8V
-1.55V
0.8V
0.8V
E21G
Note:
E21G
VEE = -5V
The ESD protection equivalent capacitance is 150 fF.
Figure 43. Equivalent Analog Clock Input Circuit and ESD Protections
VCC
VCC = +5V
+0.8V
-5.8V
-0.8V
-5.8V
-5.8V
GND = 0V
-5.8V
-5.8V
VEE
E31V
E31V
150Ω
VEE
150Ω
CLK
CLKB
Pad
capacitance
340 fF
5.8V
Pad
capacitance
340 fF
5.8V
380 µA
0.8V
0.8V
E21G
Note:
VEE = -5V
E21G
The ESD protection equivalent capacitance is 150 fF.
39
2144C–BDC–04/03
Figure 44. Equivalent Data Output Buffer Circuit and ESD Protections
VPLUSD = 0V to 2.4V
-5.8V
VEE
-5.8V
E01V
E01V
VEE
OUT
OUTB
5.8V
5.8V
Pad
capacitance
180 fF
Pad
capacitance
180 fF
0.8V
0.8V
0.8V
DVEE = -5V
E21GA
VEE = -5V
Note:
0.8V
VEE = -5V
The ESD protection equivalent capacitance is 150 fF.
Figure 45. ADC Gain Adjust Equivalent Analog Input Circuit and ESD Protections
VCC = +5V
GND
-0.8V
+0.8V
NP1032C2
-5.8V
E22V
1 kΩ
GA
Pad
capacitance
180 fF
0.8V
2 pF
0.8V
GND
5.8V
VEE
Note:
40
E22GA
500 µA
500 µA
VEE = -5V
The ESD protection equivalent capacitance is 150 fF.
TS8388B
2144C–BDC–04/03
TS8388B
Figure 46. GORB Equivalent Input Schematic and ESD Protections
GORB: Gray or Binary Select Input; Floating or Tied to VCC -> Binary
VCC = +5V
-0.8V
1 kΩ
1 kΩ
-0.8V
1 kΩ
-5.8V
VEE
E21VA
5 kΩ
GORB
Pad
capacitance
180 fF
5.8V
5.8V
250 µA
250 µA
5.8V
E31G
VEE = -5V
Note:
GND = 0V
The ESD protection equivalent capacitance is 150 fF.
Figure 47. DRRB Equivalent Input Schematic and ESD Protections
Actual Protection Range: 6.6V above VEE, in fact stress above GND are clipped by the CB diode used for Tj monitoring
VCC = +5V
GND=0V
NP1032C2
10 kΩ
200Ω
DRRB
-1.3V
Pad
capacitance
180 fF
-2.6V
5.8V
0.8V
VEE
Note:
E21G
VEE = -5V
The ESD protection equivalent capacitance is 150 fF.
41
2144C–BDC–04/03
TSEV8388B:
Device
Evaluation
Board
For complete specification, see separate TSEV8388B document.
General
Description
The TSEV8388B Evaluation Board (EB) is a board which has been designed in order to facilitate the evaluation and the characterization of the TS8388B device up to its 1.5 GHz full power
bandwidth at up to 1 GSPS in the military temperature range.
The high speed of the TS8388B requires careful attention to circuit design and layout to
achieve optimal performance.
This four metal layer board with internal ground plane has the adequate functions in order to
allow a quick and simple evaluation of the TS8388B ADC performances over the temperature
range.
The TSEV8388B Evaluation Board is very straightforward as it only implements the TS8388B
ADC, SMA connectors for input/output accesses and a 2.54 mm pitch connector compatible
with high speed acquisition system probes.
The board also implements a de-embedding fixture in order to facilitate the evaluation of the
high frequency insertion loss of the input microstrip lines, and a die junction temperature measurement setting.
The board is constituted by a sandwich of two dielectric layers, featuring low insertion loss and
enhanced thermal characteristics for operation in the high frequency domain and extended
temperature range.
The board dimensions are 130 mm x 130 mm.
The board set comes fully assembled and tested, with the TS8388B installed.
42
TS8388B
2144C–BDC–04/03
TS8388B
CBGA68 Thermal
and Moisture
Characteristics
Thermal Resistance
from Junction to
Ambient: RTHJA
The following table lists the converter thermal performance parameters of the device itself,
with no external heatsink added.
Table 9. Thermal Resitance
Air flow (m/s)
Estimated JA thermal resistance (°C/W)
0
45
0.5
35.8
1
30.8
1.5
27.4
2
24.9
2.5
23
3
21.5
4
19.3
5
17.7
Figure 48. Thermal Resistance from Junction to Ambient: RTHJA
RTHJA (°C/W)
50
40
30
20
10
0
0
1
2
3
4
5
Air flow (m/s)
Thermal Resistance
from Junction to
Case: RTHJC
Typical value for Rthjc is given to 6.7°C/W (8°C/W max).
This value does not include thermal contact resistance between package and external component (heatsink or PCBoard).
As an example, 2.0°C/W can be taken for 50 µm of thermal grease.
43
2144C–BDC–04/03
CBGA68 Board
Assembly with
External Heasink
It is recommended to use an external heatsink or PCBoard special design.
Cooling system efficiency can be monitored using the Temperature Sensing Diode, integrated
in the device.
Figure 49. CBGA68 Board Assembly
50.5
24.2
20.2
32.5
31
Moisture
Characteristics
Board
This device is sensitive to the moisture (MSL3 according to JEDEC standard):
Shelf life in sealed bag: 12 months at <40°C and <90% relative humidity (RH).
After this bag is opened, devices that will be subjected to infrared reflow, vapor-phase reflow,
or equivalent processing (peak package body temperature 220°C) must be:
•
mounted within 198 hours at factory conditions of ≤30°C/60% RH, or
•
stored at ≤20% RH.
Devices require baking, before mounting, if Humidity Indicator Card is >20% when read at
23°C ±5°C.
If baking is required, devices may be baked for:
44
•
192 hours at 40°C +5°C/-0°C and <5% RH for low-temperature device containers, or
•
24 hours at 125°C ±5°C for high temperature device containers.
TS8388B
2144C–BDC–04/03
TS8388B
Nominal CQFP68
Thermal
Characteristics
Although the power dissipation is low for this performance, the use of a heat sink is
mandatory.
Thermal Resistance
from Junction to
Ambient: RTHJA
The following table lists the converter thermal performance parameters, with or without
heatsink.
The user will find some advice on this topics below.
For the following measurements, a 50 x 50 x 16 mm heatsink has been used (see Figure 51
on page 46).
Table 10. Thermal Resitance
ja Thermal Resistance (°C/W)
CQFP68 on Board
Air Flow
(m/s)
Estimated – Without Heatsink
Targeted – With Heatsink(1)
0
50
10
0.5
40
8.9
1
35
7.9
1.5
32
7.3
2
30
6.8
2.5
28
6.5
3
26
6.2
4
24
5.8
5
23.5
5.6
Note:
1. Heatsink is glued to backside of package or screwed and pressed with thermal grease.
Figure 50. Thermal Resistance from Junction to Ambient: Rthja
60
RTHJA (°C/W)
50
40
30
Without heatsink
20
10
With heatsink
0
0
1
2
3
4
5
Air flow (m/s)
45
2144C–BDC–04/03
Thermal Resistance
from Junction to
Case: RTHJC
Typical value for Rthjc is given to 4.75°C/W.
CQFP68 Board
Assembly
Figure 51. CQFP68 Board Assembly with a 50 x 50 x 16 mm External Heatsink
28.96
24.13
Printed circuit
Aluminum heatsink
1.4
15.0
Interface: Af-filled epoxy or thermal
conductive grease - 100 µm max.
4.0
2.5
16.0
1.3
3.2
50.0
46
TS8388B
2144C–BDC–04/03
TS8388B
Enhanced CQFP68
Thermal
Characteristics
Enhanced CQFP68
Thermal Resistance
from Junction to
Case: RTHJC
The CQFP68 has been modified, in order to improve the thermal characteristics:
•
A CuW heatspreader has been added at the bottom of the package.
•
The die has been electrically isolated with the ALN substrate.
Typical value for Rthjc is given to 1.56°C/W.
This value does not include thermal contact resistance between package and external component (heatsink or PCBoard).
As an example, 2.0°C/W can be taken for 50 µm of thermal grease.
Heatsink
It is recommended to use an external heatsink, or PCBoard special design.
The stand off has been calculated to permit the simultaneous soldering of the leads and of the
heatspreader with the solder paste.
Figure 52. Enhanced CQFP68 Suggested Assembly
28.78
24.13
Printed
circuit board
CuW heatspreader
Thermal via
Solid ground plane
Cooling system efficiency can be monitored using the Temperature Sensing Diode, integrated
in the device.
47
2144C–BDC–04/03
Definitions
Definition of
Terms
(BER) Bit Error Rate
Probability to exceed a specified error threshold for a sample. An error code is a code that differs by more than ± 4 lsb from the correct code.
(FPBW) Full Power
Input Bandwidth
Analog input frequency at which the fundamental component in the digitally reconstructed output has fallen by 3 dB with respect to its low frequency value (determined by FFT analysis) for
input at Full Scale.
(SINAD) Signal to Noise
and Distortion Ratio
Ratio expressed in dB of the RMS signal amplitude, set to 1 dB below Full Scale, to the RMS
sum of all other spectral components, including the harmonics except DC.
(SNR) Signal to Noise
Ratio
Ratio expressed in dB of the RMS signal amplitude, set to 1 dB below Full Scale, to the RMS
sum of all other spectral components excluding the five first harmonics.
(THD) Total Harmonic
Distorsion
Ratio expressed in dBc of the RMS sum of the first five harmonic components, to the RMS
value of the measured fundamental spectral component.
(SFDR) Spurious Free
Dynamic Range
Ratio expressed in dB of the RMS signal amplitude, set at 1 dB below Full Scale, to the RMS
value of the next highest spectral component (peak spurious spectral component). SFDR is
the key parameter for selecting a converter to be used in a frequency domain application
(Radar systems, digital receiver, network analyzer, etc.). It may be reported in dBc (i.e.:
degrades as signal levels is lowered), or in dBFS (i.e.: always related back to converter full
scale).
(ENOB) Effective
Number Of Bits
ENOB =
SINAD - 1.76 + 20 log (A/V/2)
6.02
Where A is the actual input amplitude and V is the full scale range of the ADC under test.
(DNL) Differential Non
Linearity
The Differential Non Linearity for an output code i is the difference between the measured step
size of code i and the ideal LSB step size. DNL (i) is expressed in LSBs. DNL is the maximum
value of all DNL (i). DNL error specification of less than 1 lsb guarantees that there are no
missing output codes and that the transfer function is monotonic.
(INL) Integral Non
Linearity
The Integral Non Linearity for an output code i is the difference between the measured input
voltage at which the transition occurs and the ideal value of this transition.
INL (i) is expressed in LSBs, and is the maximum value of all |INL (i)|.
(DG) Differential Gain
The peak gain variation (in percent) at five different DC levels for an AC signal of 20% Full
Scale peak to peak amplitude. FIN = 5 MHz (TBC).
(DP) Differential Phase
Peak Phase variation (in degrees) at five different DC levels for an AC signal of 20% Full
Scale peak to peak amplitude. FIN = 5 MHz (TBC).
(TA) Aperture Delay
Delay between the rising edge of the differential clock inputs (CLK, CLKB) (zero crossing
point), and the time at which (VIN, VINB) is sampled.
48
TS8388B
2144C–BDC–04/03
TS8388B
(JITTER) Aperture
Uncertainty
Sample to sample variation in aperture delay. The voltage error due to jitter depends on the
slew rate of the signal at the sampling point.
(TS) Settling Time
Time delay to achieve 0.2% accuracy at the converter output when a 80% Full Scale step
function is applied to the differential analog input.
(ORT) Overvoltage
Recovery Time
Time to recover 0.2% accuracy at the output, after a 150% full scale step applied on the input
is reduced to midscale.
(TOD) Digital Data
Output Delay
Delay from the falling edge of the differential clock inputs (CLK, CLKB) (zero crossing point) to
the next point of change in the differential output data (zero crossing) with specified load.
(TD1) Time Delay from
Data to Data Ready
Time delay from Data transition to Data ready.
(TD2) Time Delay from
Data Ready to Data
General expression is TD1 = TC1 + TDR - TOD with TC = TC1 + TC2 = 1 encoding clock
period.
(TC) Encoding Clock
Period
TC1 = Minimum clock pulse width (high) TC = TC1 + TC2
(TPD) Pipeline Delay
Number of clock cycles between the sampling edge of an input data and the associated output
data being made available, (not taking in account the TOD). For the TS8388B the TPD is 4
clock periods.
(TRDR) Data Ready
Reset Delay
Delay between the falling edge of the Data Ready output asynchronous Reset signal (DDRB)
and the reset to digital zero transition of the Data Ready output signal (DR).
(TR) Rise Time
Time delay for the output DATA signals to rize from 20% to 80% of delta between low level
and high level.
(TF) Fall Time
Time delay for the output DATA signals to fall from 80% to 20% of delta between low level and
high level.
(PSRR) Power Supply
Rejection Ratio
Ratio of input offset variation to a change in power supply voltage.
(NRZ) Non Return to
Zero
When the input signal is larger than the upper bound of the ADC input range, the output code
is identical to the maximum code and the Out of Range bit is set to logic one. When the input
signal is smaller than the lower bound of the ADC input range, the output code is identical to
the minimum code, and the Out of range bit is set to logic one. (It is assumed that the input signal amplitude remains within the absolute maximum ratings).
(IMD) InterModulation
Distortion
The two tones intermodulation distortion (IMD) rejection is the ratio of either input tone to the
worst third order intermodulation products. The input tones levels are at -7 dB Full Scale.
(NPR) Noise Power
Ratio
The NPR is measured to characterize the ADC performance in response to broad bandwidth
signals. When using a notch-filtered broadband white-noise generator as the input to the ADC
under test, the Noise Power Ratio is defined as the ratio of the average out-of-notch to the
average in-notch power spectral density magnitudes for the FFT spectrum of the ADC output
sample test.
TC2 = Minimum clock pulse width (low)
49
2144C–BDC–04/03
Ordering
Information
Table 11. Ordering Information
Part Number
Package
JTS8388B-1V1B
Die
JTS8388B-1V2B
Die
TS8388BCF
CQFP 68
C" grade
0°C < Tc; Tj < 90°C
Standard
TS8388BVF
CQFP 68
"V" grade
-40°C < Tc; Tj < 110°C
Standard
TS8388BMF
CQFP 68
"M" grade
-55°C < Tc; Tj < 125°C
Standard
TS8388BMF B/Q
CQFP 68
"M" grade
-55°C < Tc; Tj < 125°C
Mil-PRF-38535,
QML level Q
TS8388BMF B/T
CQFP 68
"M" grade
-55°C < Tc; Tj < 125°C
Standard + 3 temperatures
test (min, ambient, max)
TS8388BCFS
CQFP 68 with
heatspreader
"C" grade
0°C < Tc; Tj < 90°C
Standard
TS8388BVFS
CQFP 68 with
heatspreader
"V" grade
-40°C < Tc; Tj < 110°C
Standard
TS8388BMFS
CQFP 68 with
heatspreader
"M" grade
-55°C < Tc; Tj < 125°C
Standard
TS8388BMFS B/Q
CQFP 68 with
heatspreader
"M" grade
-55°C < Tc; Tj < 125°C
Mil-PRF-38535,
QML level Q
TS8388BMFS B/T
CQFP 68 with
heatspreader
"M" grade
-55°C < Tc; Tj < 125°C
Standard + 3 temperatures
test (min, ambient, max)
TS8388BMFS9NB2
CQFP 68 with
heatspreader
"M" grade
-55°C < Tc; Tj < 125°C
. ESA/SCC9000 Screening
. Non ESA/SCC qualified
. Level B selection
. Lot Acceptance Test 2
TS8388BMFS9NB3
CQFP 68 with
heatspreader
"M" grade
-55°C < Tc; Tj < 125°C
. ESA/SCC9000 Screening
. Non ESA/SCC qualified
. Level B selection
. Lot Acceptance Test 3
TS8388BMFS9NC2
CQFP 68 with
heatspreader
"M" grade
-55°C < Tc; Tj < 125°C
. ESA/SCC9000 Screening
. Non ESA/SCC qualified
. Level C selection
. Lot Acceptance Test 2
TS8388BMFS9NC3
CQFP 68 with
heatspreader
"M" grade
-55°C < Tc; Tj < 125°C
. ESA/SCC9000 Screening
. Non ESA/SCC qualified
. Level C selection
. Lot Acceptance Test 3
50
Temperature Range
Screening
Comments
Ambient
Visual inspection
ON REQUEST ONLY
(Please contact Marketing)
Ambient and High
temperature (Tj = 125°C)
Visual inspection
ON REQUEST ONLY
(Please contact Marketing)
DSCC 5962-0050401QYC
DSCC 5962-0050401QXC
TS8388B
2144C–BDC–04/03
TS8388B
Table 11. Ordering Information
Part Number
Package
Temperature Range
Screening
Comments
TS8388BCGL
CBGA 68
"C" grade
0°C < Tc; Tj < 90°C
Standard
TS8388BVGL
CBGA 68
"V" grade
-40°C < Tc; Tj < 110°C
Standard
TSEV8388BF
CQFP 68
Ambient
Prototype
Evaluation board (delivered
with heatsink)
TSEV8388BFZA2
CQFP 68
Ambient
Prototype
Evaluation board with digital
receivers (delivered with
heatsink)
TSEV8388BGL
CBGA 68
Ambient
Prototype
Evaluation board (delivered
with heatsink)
TSEV8388BGLZA2
CBGA 68
Ambient
Prototype
Evaluation board with digital
receivers (delivered with
heatsink)
51
2144C–BDC–04/03
CBGA68
Capacitors and
Resistors Implant
Figure 53. TS8388BGL Capacitors and Resistors Implant
GND
0.9 mm
100 pF
DVEE
∅ 7.0 mm
CLKB
CLK
100 pF
100 pF
100 pF
50Ω
50Ω
GND
GND
GND
GND
GND
GORB
GND
GND
100 pF
100 pF
100 pF
GND
VEE
GND
VCC
100 pF
VCC
VEE
VEE
VCC
0.9 mm
100 pF
GND
VCC
GND
VINB
VIN
GAIN
100 pF
50Ω
50Ω
100 pF
GND
GND
GND
VCC
0.9 mm
0.9 mm
Only on-package marking
Electrically isolated
Note:
52
R and C are discrete components of 0603 size (1.6 x 0.8 mm).
TS8388B
2144C–BDC–04/03
TS8388B
Outline
Descriptions
Figure 54. Package Dimension – 68 Pins CBGA
0.20 T
CBGA 68 package.
AL203 substrate.
Package design.
Corner balls (x4) are not connected (mechanical ball).
Balls : 1.27 mm pitch on 11x11 grid.
Top side with
soldered R, C
devices
View balls side
-T-
0.95 max
(using solder
Sn/Pb 63/37)
Balls side
1.27
100 pF
11
10
Balls
Sn/Pb 63/37
AI203 substrate
9
7.84
5
0.15
7.84
7
6
AI203 Ceramic
Cap.
Glued and embedded
in substrate
15.00 ± 0.15 mm
8
4
3
50 Ω
2
1.00
1
Ball
A1 Index
other side
A
B
C
D
E
F
G
H
J
K
L
-B-
D
1.45 ± 0.12
15.00 ± 0.15 mm
-A-
1.27 ref
72x∅ D = 0.80 ± 0.10 mm
0.40 T A B (Position of array of balls / edges A and B)
0.15 T
(Position of balls within array)
Detail of
ball x2
0.63 ± 0.10
All units in mm
53
2144C–BDC–04/03
Figure 55. Package Dimension – 68-lead Ceramic Quad Flat Pack (CQFP)
TOP VIEW
0.8 BCS
20.32 BSC
M 0.005 ∅
Y
X
Z
CQFP 68
28.78 - 29.13
1.133 - 1.147
0.050 BCS
1.27 BSC
Pin N° 1 index
24.13 ± 0.152
0.950 ± 0.006
0.58 ± 0.05
0.023 ± 0.002
Outline
Dimensions
0.950 ± 0.006
24.13 ± 0.152
0.027 - 0.037
0.70 - 0.95
0° - 8°
0.46 - 0.88
0.018 - 0.035
0.004
1.9 ± 0.20
0.075 ± 0.008
3.43 Max
0.135 Max
1.133 - 1.147
28.78 - 29.13
54
0.005 - 0.010
0.13 - 0.25
TS8388B
2144C–BDC–04/03
TS8388B
Figure 56. Package Dimension – 68-lead Enhanced CQFP with Heatspreder
0.8 BCS
20.32 BSC
Y
X
Z
CQFP 68
28.78 - 29.13
1.133 - 1.147
24.13 ± 0.152
0.950 ± 0.006
0.050 BCS
1.27 BSC
Pin N° 1 index
M 0.005 ∅
0.58 ± 0.05
0.023 ± 0.002
TOP VIEW
0.950 ± 0.006
24.13 ± 0.152
0.51 ± 0.13
0.020 ± 0.005
0.787
0.0310
0.978
0.0385
0.18 ± 0.13
0.007 ± 0.005
1.133 - 1.147
28.78 - 29.13
0° - 8°
0.027 - 0.037
0.70 - 0.95
0.005 - 0.010
0.13 - 0.25
55
2144C–BDC–04/03
Datasheet
Status
Description
Table 12. Datasheet Status
Datasheet Status
Validity
Objective specification
This datasheet contains target and
goal specifications for discussion with
customer and application validation.
Before design phase
Target specification
This datasheet contains target or
goal specifications for product
development.
Valid during the design phase
Preliminary specification
α-site
This datasheet contains preliminary
data. Additional data may be
published later; could include
simulation results.
Valid before characterization
phase
Preliminary specification
β-site
This datasheet contains also
characterization results.
Valid before the
industrialization phase
Product specification
This datasheet contains final product
specification.
Valid for production purposes
Limiting Values
Limiting values given are in accordance with the Absolute Maximum Rating System (IEC 134). Stress
above one or more of the limiting values may cause permanent damage to the device. These are
stress ratings only and operation of the device at these or at any other conditions above those given in
the Characteristics sections of the specification is not implied. Exposure to limiting values for
extended periods may affect device reliability.
Application Information
Where application information is given, it is advisory and does not form part of the specification.
Life Support
Applications
56
These products are not designed for use in life support appliances, devices or systems where
malfunction of these products can reasonably be expected to result in personal injury. Atmel
customers using or selling these products for use in such applications do so at their own risk
and agree to fully indemnify Atmel for any damages resulting from such improper use or sale.
TS8388B
2144C–BDC–04/03
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2144C–BDC–04/03