INTERSIL HI5710A_00

HI5710A
®
August 2000
Features
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8-INT
1-88
10-Bit, 20 MSPS A/D Converter
Description
• Resolution ±0.5 LSB (DNL) . . . . . . . . . . . . . . . . . . 10-Bit
The HI5710A is a low power, 10-bit, CMOS analog-to-digital
converter. The use of a 2-step architecture realizes low
power consumption, 150mW, and a maximum conversion
speed of 20MHz with only a 3 clock cycle data latency. The
HI5710A can be powered down, disabling the chip and the
digital outputs, reducing power to less than 5mW. A built-in,
user controllable, calibration circuit is used to provide low
linearity error, 1 LSB. The low power, high speed and small
package outline make the HI5710A an ideal choice for CCD,
battery, and high channel count applications.
• Maximum Sampling Frequency . . . . . . . . . . . 20 MSPS
• Low Power Consumption
(Reference Current Excluded) . . . . . . . . . . . . . . 150mW
• Standby Mode Power . . . . . . . . . . . . . . . . . . . . . . . 5mW
• No Sample and Hold Required
• TTL Compatible Inputs
• Three-State TTL Compatible Outputs
• Single +5V Analog Power Supply
• Data Communications
The HI5710A does not require an external sample and hold
but requires an external reference and includes force and
sense reference pins for increased accuracy. The digital
outputs can be inverted, with the MSB controlled separately,
allowing for various digital output formats. The HI5710A
includes a test mode where the digital outputs can be set to
a fixed state to ease in-circuit testing.
• Image Scanners
Part Number Information
• Single +3.3V or +5V Digital Power Supply
Applications
• Video Digitizing - Multimedia
• Medical Imaging
• Video Recording Equipment
TEMP.
RANGE (oC)
PART NO.
• Camcorders
HI5710AJCQ
• QAM Demodulation
Pinout
-20 to 75
PACKAGE
48 Ld MQFP
PKG. NO.
Q48.7x7-S
TSTR
VIN
AT
NC
TS
CAL
AVSS
NC
DVDD
AVSS
NC
DVSS
HI5710A (MQFP)
TOP VIEW
1
48 47 46 45 44 43 42 41 40 39 38 37
36
2
35
VRB
D2
D3
3
34
VRB
4
33
D4
5
32
DVSS
6
31
NC
NC
NC
DVDD
D0
D1
AVss
27
AVSS
11
12
26
AVDD
25
13 14 15 16 17 18 19 20 21 22 23 24
AVDD
D8
TO
D9
CAUTION: These devices are sensitive to electrostatic discharge; follow proper IC Handling Procedures.
1-888-INTERSIL or 321-724-7143 | Intersil (and design) is a registered trademark of Intersil Americas Inc.
Copyright © Intersil Americas Inc. 2002. All Rights Reserved
1
CE
10
OE
VRT
AVSS
MINV
CLK
28
TESTMODE
LINV
9
SEL
8
D6
D7
AVDD
VRT
29
RESET
DVSS
30
TIN
7
D5
File Number
3921.6
HI5710A
Functional Block Diagram
VIN 39
S/H
AMP
+
∑
-
8x
12 D9 (MSB)
COURSE
CORRECTION
AND
LATCH
VRT 29
VRT 30
DAC
FINE
COMPARATOR
AND
ENCODE
CALIBRATION
UNIT
CE
24
D6
FINE
LATCH
5
D4
4
D3
3
D2
2
D1
21 MINV
20 LINV
VRB 35
23
9
1 D0 (LSB)
VRB 34
OE
10 D7
8 D5
COURSE
COMPARATOR
AND
ENCODE
CLK 22
11 D8
19 TESTMODE
TIMING GEN
41 CAL
AUTO CALIBRATION
PULSE GENERATOR
17 SEL
15 RESET
2
HI5710A
Absolute Maximum Ratings TA = 25oC
Thermal Information
Supply Voltage, AVDD , DVDD . . . . . . . . . . . . . . . . . . . . . . . . . . . 7V
Reference Voltage, V RT , VRB . . . . . . . . . VDD + 0.5V to VSS - 0.5V
Analog Input Voltage, VIN . . . . . . . . . . . . VDD + 0.5V to VSS - 0.5V
Digital Input Voltage, V IH , VIL . . . . . . . . . VDD + 0.5V to VSS - 0.5V
Digital Output Voltage, V OH , VOL . . . . . . VDD + 0.5V to VSS - 0.5V
Thermal Resistance (Typical, Note 1)
θJA (oC/W)
MQFP Package . . . . . . . . . . . . . . . . . . . . . . . . . . . .
111
Maximum Junction Temperature. . . . . . . . . . . . . . . . . . . . . . . 150oC
Maximum Storage Temperature Range, TSTG . . . . . -65oC to 150oC
Maximum Lead Temperature (Soldering 10s). . . . . . . . . . . . . 300oC
(Lead Tips Only)
Operating Conditions
Analog Input Range, VIN . . . . . . . .(VRT - VRB) (1.8VP-P to 2.8VP-P)
Clock Pulse Width
tPW1. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25ns (Min)
tPW0. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25ns (Min)
Temperature, TA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -20oC to 75oC
Supply Voltage
AVDD , AVSS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . +5V ±0.25V
DV DD , DVSS . . . . . . . . . . . . . . . . . . . . . . . . . . +3.3V to 5V ±0.25V
| DGND-AGND| . . . . . . . . . . . . . . . . . . . . . . . . . . . .0mV to 100mV
Reference Input Voltage
VRB . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1.8V to 2.8V
VRT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3.6V to 4.6V
CAUTION: Stresses above those listed in “Absolute Maximum Ratings” may cause permanent damage to the device. This is a stress only rating and operation
of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied.
NOTE:
1. θJA is measured with the component mounted on an evaluation PC board in free air.
Electrical Specifications
fC = 20 MSPS, AV DD = +5V, DVDD = +3.3V, V RB = 2.0V, VRT = 4.0V, TA = 25oC (Note 2)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
EOT
40
90
140
mV
EOB
-120
-70
-20
mV
-
±1.3
±2.0
LSB
-
±0.5
±1.0
LSB
20
-
-
MSPS
-
-
0.5
MSPS
SYSTEM PERFORMANCE
Offset Voltage
Integral Non-Linearity, INL
VIN = 2.0V to 4.0V
Differential Non-Linearity, DNL
DYNAMIC CHARACTERISTICS
Maximum Conversion Speed, fC
fIN = 1kHz Ramp
Minimum Conversion Speed, fC
Effective Number of Bits, ENOB
fIN = 3MHz
-
8.7
-
BIts
Signal to Noise and Distortion, SINAD
fIN = 100kHz
-
53
-
dB
fIN = 500kHz
-
52
-
dB
fIN = 1MHz
-
53
-
dB
fIN = 3MHz
-
54
-
dB
fIN = 7MHz
-
47
-
dB
fIN = 10MHz
-
45
-
dB
fIN = 100kHz
-
60
-
dB
fIN = 500kHz
-
59
-
dB
fIN = 1MHz
-
60
-
dB
fIN = 3MHz
-
65
-
dB
fIN = 7MHz
-
50
-
dB
fIN = 10MHz
-
49
-
dB
NTSC 40 IRE Mod Ramp, fC = 14.3 MSPS
-
1.0
-
%
-
0.3
-
Degree
Spurious Free Dynamic Range, SFDR
Differential Gain Error, DG
Differential Phase Error, DP
3
HI5710A
Electrical Specifications
fC = 20 MSPS, AVDD = +5V, DVDD = +3.3V, VRB = 2.0V, VRT = 4.0V, TA = 25oC (Note 2) (Continued)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
-
100
-
MHz
VIN = 4V
-
-
50
µA
VIN = 2V
-50
-
-
µA
VIN = 2.5V + 0.07VRMS
-
9
-
pF
Reference Pin Current, IRT
RESET = Low
5
7
11
mA
Reference Pin Current, IRB
RESET = Low
-11
-7
-5
mA
180
280
380
Ω
2.3
-
-
V
-
-
0.80
V
VIH = DVDD
-
-
5
µA
VIL = 0V
-
-
5
µA
VOH = DVDD -0.5V
3.5
-
-
mA
VOL = 0.4V
3.5
-
-
mA
VOH = DVDD
-
-
1
µA
VOL = 0V
-
-
1
µA
8
13
18
ns
tPZL
10
15
20
ns
tPLZ
20
25
30
ns
tPZH
10
15
20
ns
tPHZ
20
25
30
ns
2
4
6
ns
20
27
34
mA
-
3
5
mA
-
-
1.0
mA
-
-
1.0
µA
ANALOG INPUTS
Analog Input Bandwidth (-3dB), BW
Analog Input Current
Analog Input Capacitance, C IN
REFERENCE INPUT
Reference Resistance (V RT to VRB), RREF
DIGITAL INPUTS
Digital Input Voltage
VIH
AVDD = 4.75V to 5.25V
VIL
Digital Input Current
IIH
DVDD = Max
IIL
DIGITAL OUTPUTS
Digital Output Current
IOH
OE = AVSS , DVDD = Min
IOL
Digital Output Leakage Current
IOZH
OE = AVDD , DVDD = Max
IOZL
TIMING CHARACTERISTICS
Output Data Delay, tDL
Output Enable/Disable Delay
Load is One TTL Gate
Sampling Delay, tSD
POWER SUPPLY CHARACTERISTIC
Analog Supply Current, IA DD
fIN = 1kHz Ramp Wave Input
Digital Supply Current, IDDD
Analog Standby Current
CE = High
Digital Standby Current
NOTE:
2. Electrical specifications guaranteed only under the stated operating conditions.
4
HI5710A
5
HI5710A
Timing Diagrams
tPW1
tPW0
1.65V
1.65V
CLOCK
tSD
N+2
N+1
ANALOG INPUT
N
N+3
N+4
N-3
DATA OUTPUT
N-2
N-1
N
1.65V (DVDD = 3.3V)
2.5V (DVDD = 5.0V)
tDL
= INDICATES POINT AT WHICH ANALOG DATA IS SAMPLED
FIGURE 1.
tPLZ
tPHZ
1.65V (DVDD = 3.3V)
2.5V (DVDD = 5.0V)
tPZL
tPZH
1.65V (DVDD = 3.3V)
2.5V (DVDD = 5.0V)
OUTPUT ENABLE ( OE)
DATA OUTPUT
ACTIVE
HIGH IMPEDANCE
FIGURE 2.
6
HI5710A
Calibration Timing Diagrams
10ns
OR MORE
7 CLOCKS
CLK
CAL
1 CLOCK OR MORE
D5 TO D9
D0 TO D4
FIGURE 3. EXTERNAL CALIBRATION PULSE TIMING DIAGRAM
INPUT
CLK
CAL
FIGURE 4A. CALIBRATION DURING H SYNC
INPUT
CLK
CAL
FIGURE 4B. CALIBRATION DURING V SYNC
FIGURE 4. EXAMPLES OF EXTERNAL CALIBRATION PULSE INPUT FOR VIDEO APPLICATIONS
7
HI5710A
Typical Performance Curves
MAXIMUM OPERATING FREQUENCY (MHz)
SUPPLY CURRENT (mA)
28
fC = 20MHz
fIN = 1kHz RAMP WAVE
AVDD = 5.0V
DVDD = 3.3V
27
26
25
24
-20
0
25
50
75
35
fIN = 1kHz RAMP WAVE
AVDD = 5.0V
DVDD = 3.3V
30
25
20
-20
100
FIGURE 5. SUPPLY CURRENT vs AMBIENT TEMPERATURE
AVDD = 5.0V
DVDD = 3.3V
fC = 1MHz
CL = 20pF
SAMPLING DELAY (ns)
OUTPUT DATA DELAY (ns)
50
75
100
8
15
13
11
25
FIGURE 6. MAXIMUM OPERATING FREQUENCY vs AMBIENT
TEMPERATURE
19
17
0
AMBIENT TEMPERATURE (oC)
AMBIENT TEMPERATURE (oC)
-20
0
25
50
6
AVDD = 5.0V
DVDD = 3.3V
fC = 1MHz
4
2
-20
75
0
25
50
75
AMBIENT TEMPERATURE (oC)
AMBIENT TEMPERATURE (oC)
FIGURE 7. OUTPUT DATA DELAY vs AMBIENT TEMPERATURE
FIGURE 8. SAMPLING DELAY vs AMBIENT TEMPERATURE
8
HI5710A
Typical Performance Curves
(Continued)
65
80
60
75
70
65
50
DVDD = 3.3V
DVDD = 5V
45
40
SFDR (dB)
SINAD (dB)
55
AVDD = 5.0V
DVDD = 3.3V
fC = 20MHz
VIN = 2VP-P
TA = 25 oC
35
30
25
0.1
60
55
50
AVDD = 5.0V
DVDD = 3.3V
fC = 20MHz
VIN = 2VP-P
TA = 25 oC
45
40
35
1
10
30
100
0.1
1
10
INPUT FREQUENCY (MHz)
INPUT FREQUENCY (MHz)
FIGURE 10. SFDR vs INPUT FREQUENCY
10
2
9
1
OUTPUT LEVEL (dB)
EFFECTIVE NUMBER OF BITS (BITS)
FIGURE 9. SINAD vs INPUT FREQUENCY
8
DVDD = 3.3V
DVDD = 5V
7
AVDD = 5.0V
DVDD = 3.3V
fC = 20MHz
VIN = 2VP-P
TA = 25 oC
6
5
4
0
-1
-2
AVDD = 5.0V
DVDD = 3.3V
fC = 20MHz
VIN = 2VP-P
TA = 25oC
-3
-4
0.1
1
10
-5
100
100K
1M
INPUT FREQUENCY (MHz)
100M
FIGURE 12. INPUT BANDWIDTH
80
10
EFFECTIVE NUMBER OF BITS (BITS)
TA = 25oC
60
INPUT CURRENT (mA)
10M
INPUT FREQUENCY (Hz)
FIGURE 11. EFFECTIVE BITS vs INPUT FREQUENCY
40
20
0
-20
-40
-60
-80
100
9.5
fIN = 1MHz
DVDD = 5V/3.3V
9
8.5
8
fIN = 5MHz
7.5
DVDD = 5V
fIN = 5MHz
7
DVDD = 3.3V
6.5
6
2
2.2
2.4
2.6
2.8
3
3.2
3.4
3.6
3.8
5
4
10
15
20
25
CLOCK FREQUENCY
INPUT VOLTAGE (V)
FIGURE 13. ANALOG INPUT CURRENT vs INPUT VOLTAGE
FIGURE 14. ENOB vs CLOCK FREQUENCY
9
30
HI5710A
Typical Performance Curves
(Continued)
-25
59
DVDD = 5V
-30
57
-35
55
-45
-50
SNR (dB)
THD (dB)
-40
DVDD = 5V
-55
DVDD = 3.3V
-60
53
DVDD = 3.3V
51
49
-65
47
-70
-75
0.1
1
10
45
100
100
INPUT FREQUENCY (MHz)
FIGURE 15. THD vs INPUT FREQUENCY
1,000
10,000
INPUT FREQUENCY (MHz)
100,000
FIGURE 16. SNR vs INPUT FREQUENCY
Pin Description and I/O Pin Equivalent Circuit
PIN
NUMBER
1 to 5,
8 to 12
SYMBOL
D0 to D9
EQUIVALENT CIRCUIT
DESCRIPTION
Digital Outputs: D0 (LSB) to D9 (MSB).
DVDD
D1
DVSS
13
TO
Test Pin, Leave Pin Open.
7, 45
DVDD
Digital VDD .
6, 16, 48
DVSS
Digital VSS .
27, 28,
36, 43, 44
AVSS
Analog VSS .
17
SEL
Controls calibration input pulse selection after
completion of the internal start-up calibration function.
High: Selects the internal auto calibration pulse
generation function
Low: Selects the external calibration pulse input, CAL
pin 41.
AVDD
17
AVSS
10
HI5710A
Pin Description and I/O Pin Equivalent Circuit
PIN
NUMBER
SYMBOL
22
CLK
(Continued)
EQUIVALENT CIRCUIT
DESCRIPTION
Clock Pin.
AVDD
22
AVSS
41
CAL
Calibration Pulse Input, calibration starts on a falling
edge, normally high.
AVDD
41
AVSS
15
RESET
Calibration Circuit Reset and Internal Calibration
Function Restart, resets with a negative pulse,
normally high.
AVDD
15
AVSS
14
TIN
29, 30
VRT
34, 35
VRB
Factory Test Signal Input, normally tied to AVSS or
AVDD .
Reference Top, normally 4.0V.
AVDD
Reference Bottom, normally 2.0V.
29, 30
AVSS
34, 35
38
AT
Factory Test Signal Output, leave pin open.
42
TS
Factory Test Signal Input, tie to AVDD .
37
TSTR
Factory Test Signal Input, tie to AVSS .
11
HI5710A
Pin Description and I/O Pin Equivalent Circuit
PIN
NUMBER
SYMBOL
23
OE
(Continued)
EQUIVALENT CIRCUIT
DESCRIPTION
D0 to D9 Output Enable.
Low: Outputs Enabled.
High: High Impedance State.
AVDD
23
AVSS
24
CE
Chip Enable.
Low: Active State.
High: Standby State.
AVDD
24
AVSS
19
TESTMODE
Test Mode.
High: Normal Output State.
Low: Output fixed.
AVDD
19
AVSS
20
LINV
Output Inversion.
High: D0 to D8 are inverted.
Low: D0 to D8 are normal.
AVDD
20
AVSS
21
MINV
Output Inversion.
High: D9 is inverted.
Low: D9 is normal.
AVDD
21
AVSS
18, 25, 26
AV DD
39
VIN
Analog VDD .
Analog Input.
AVDD
39
-
+
AVSS
12
HI5710A
A/D OUTPUT CODE TABLE
DIGITAL OUTPUT CODE
INPUT SIGNAL
VOLTAGE
STEP
MSB
VRT
1023
1
•
•
•
•
•
•
•
•
•
•
•
512
1
0
0
0
511
0
1
1
1
VRB
0
LSB
1
1
1
1
1
1
1
1
1
1
0
0
0
0
0
0
0
1
1
1
1
1
1
1
0
0
0
0
0
0
•
•
•
•
•
•
•
•
•
0
0
0
0
0
NOTE:
3. This table shows the correlation between the analog input voltage and the digital output code. (TESTMODE = 1, MINV and LINV= 0)
DIGITAL OUTPUT DATA FORMAT TABLE
TESTMODE
LINV
MINV
D0
D1
D2
D3
D4
D5
D6
D7
D8
D9
1
0
0
N
N
N
N
N
N
N
N
N
N
1
1
0
I
I
I
I
I
I
I
I
I
N
1
0
1
N
N
N
N
N
N
N
N
N
I
1
1
1
I
I
I
I
I
I
I
I
I
I
0
0
0
1
0
1
0
1
0
1
0
1
0
0
1
0
0
1
0
1
0
1
0
1
0
0
0
0
1
1
0
1
0
1
0
1
0
1
1
0
1
1
0
1
0
1
0
1
0
1
0
1
NOTES:
4. This table shows the output state for the combination of TESTMODE, LINV, and MINV states.
5. N: Non-Inverted Output.
6. I: Inverted Output.
Detailed Description
type A/D converters. However, it is necessary to drive the input
with an amplifier with sufficient bandwidth and drive capability.
Op amps such as the HA5020 should make an excellent input
amplifier depending on the application requirements. In order to
prevent parasitic oscillation, it may be necessary to insert a
resistor between the output of the amplifier and the A/D input.
Be sure to consider the amplifiers settling time in CCD
applications or where step inputs are expected.
The HI5710A is a two step A/D converter featuring a 5-bit
upper comparator group and a 5-bit lower comparator group.
A user controllable internal calibration unit is used to
improve linearity.
The voltage references must be supplied externally, with VRB
and VRT typically being set to 2.0V and 4.0V respectively.
Reference Input
Both chip enable and output enable pins are provided for
flexibility and to reduce power consumption. The digital
outputs can be inverted by control inputs LINV and MINV,
where LINV controls outputs D0 through D8 and MINV
controls output D9 (MSB). This allows for various digital
output data formats, such as straight binary, inverted binary,
offset two’s complement or inverted offset two’s
complement.
The analog input voltage range of the A/D is set by the
voltage difference between the VRT and VRB voltage
references. The HI5710A is designed for use with external
voltage references of 2.0V and 4.0V on VRB and V RT ,
respectively. The analog input voltage range of the A/D will
now be from 2.0V to 4.0V. The VRB voltage reference range
is 1.8V to 2.8V and the VRT voltage reference range is 3.6V
to 4.6V. The voltage difference between the VRT and VRB
voltage references, (VRT - VRB), can range from 1.8V to
2.8V.
Analog Input
The analog input typically requires a 2V P-P full scale input
signal. The full scale input can range from 1.8V P-P to
2.8VP-P dependent on the voltage references used.
The VRT and VRB voltage reference input pins must be
decoupled to analog ground to minimize noise on these
references. A 0.1µF capacitor is usually adequate.
The input capacitance is small when compared with other flash
13
HI5710A
generator automatically generates these pulses internally
and completes the initial calibration process. The following
five conditions must be satisfied in order for the auto
calibration pulse generator power-up calibration process to
be initiated :
Clock Input
The HI5710A samples the input signal on the rising edge of the
clock with the digital data being latched at the digital outputs
(D0 - D9) after 3 clock cycles. The HI5710A is designed for use
with a 50% duty cycle square wave, but a 10% variation should
not affect performance.
a) The voltage between AVDD and AVSS is approximately
2.5V or more.
The clock input can be driven from +3.3V CMOS or +5V
TTL/CMOS logic. When using a +3.3V digital supply, HC or
AC CMOS logic will work well.
b) The voltage between VRT and VRB is approximately 1.0V
or more.
Digital Inputs
c) The RESET control input pin (Pin 15) must be high
(logic 1).
The digital inputs can be driven from +3.3V CMOS or +5V
TTL/CMOS logic. When using a +3.3V digital supply, HC or
AC CMOS logic will work well.
d) The CE control input pin (Pin 24) must be low (logic 0).
e) Condition b must be met after condition a.
Digital Outputs
Once all five of these conditions is satisfied the power-up
calibration pulses are generated. These power-up calibration
pulses are derived from a divided-by sixteen sample clock
(CLK/16). A 14-bit counter is also counting the CLK/16
signal and when the 14-bit counter reaches the end of its
count range the carry out from the counter is used to gate off
or mask the CLK/16 power-up calibration pulses.
The digital outputs are CMOS outputs. The LINV control
input will invert outputs D0 through D8 and MINV control
input will invert output D9 (MSB). This allows the user to set
the digital output data for a number of different digital
formats. The outputs can also be three-stated by pulling the
OE control input high.
The digital output supply can run from +3.3V or +5V. The
digital outputs will generate less radiated noise using +3.3V,
but the outputs will have less drive capability. The digital
outputs will only swing to DVDD , therefore exercise care if
interfacing to +5V logic when using a +3.3V supply.
The time required for the power-up calibration process to be
completed after the above five conditions has been met can
be calculated using the following equation:
The digital output data can also be set to a fixed,
predetermined state, through the use of the TESTMODE,
LINV and MINV control input signals, see the Digital Output
Data Format table. By setting the TESTMODE pin low, the
outputs go to a defined digital pattern. This pattern is varied
by the MINV and LINV control inputs. This feature can be
used for in-circuit testing of the digital output data bus.
For example, if the sample clock frequency is 20MHz, the
time required for the power-up calibration process to be
completed, after the above five conditions has been met, is
Calibration Function
The auto calibration pulse generator provides the user with
the choice of internal or external periodic calibration pulse
generation following the completion of the power-up
calibration process. The selection of internal or external
periodic calibration pulse generation is made through the
use of the SEL control input pin (pin 17). Setting the SEL
control input pin high (logic 1) selects the internal periodic
calibration pulse generation function. Setting the SEL control
input pin low (logic 0) selects the external calibration pulse
input pin (CAL, pin 41).
tPower-Up Cal = (24 x 214)/(fCLK) = 218/fCLK .
tPower-Up Cal = 218/fCLK = 218/20x106 = 262,144/20 x 106 ,
tPower-Up Cal = 13.1ms.
Auto Calibration Pulse Generation Function
The HI5710A has a built-in calibration unit which is designed
to provide superior linearity by correcting the gain error of
the subrange amplification circuitry. In addition to the
calibration unit, the HI5710A provides a built-in auto
calibration pulse generation function. Figure 20 shows a
functional block diagram of the auto calibration pulse
generator circuit.
The calibration pulse generation functions provided can be
subdivided into four operational areas. The first function is
the generation of the calibration pulses required to complete
the initial (power-up) calibration process when power is first
supplied to the converter. The next two functions
accommodated are the generation of periodic calibration
pulses, either internally or externally, to maintain calibration.
The last function is the provision for externally initiating or reinitiating the power-up calibration process.
For the case where the internal periodic calibration pulse
generation function has been chosen, SEL control input pin
high, the auto calibration pulse generator periodically
generates calibration pulses internally so that calibration is
performed constantly without the need to provide calibration
input pulses from an external source. These periodic
calibration pulses are derived from the divided-by sixteen
sample clock (CLK/16). The CLK/16 signal drives a 24-bit
counter which generates a carry-out that is used as the
internal calibration pulse. The time between calibration
pulses when using the internal auto calibration pulse
generator can be calculated using the following equation:
Power-up Calibration Function
The initial power-up calibration requires over 600 calibration
pulses in order to complete the calibration process when
power is first applied to the converter. The power-up
calibration function provided by the auto calibration pulse
tInternal Cal Pulse = (24 x 224)/(fCLK) = 228/fCLK .
14
HI5710A
Initiating/Re-Initiating Power-up Calibration Function
For example, if the sample clock frequency is 20MHz, the
time between internal auto calibration pulses is:
The power-up calibration function can be initiated/re-initiated
after the power supply voltage and the reference voltages
are stabilized by using the CE (pin 24) or RESET (pin 15)
control input pins. This might prove useful in a situation
where the turn-on characteristics of the power supply and
reference voltages is unstable/indeterminate or where the
sequence of power-up does not meet the required conditions
stated earlier.
tInternal Cal Pulse = 228/fCLK = 228/20 x 106 =
268,435,456/20 x 106,
tInternal Cal Pulse = 13.4s.
Since a calibration is completed once every seven
calibration pulses, the time required to complete a
calibration cycle is:
Power, Grounding, and Decoupling
tInternal Cal Cycle = (7 x 228)/fCLK .
To reduce noise effects, keep the analog and digital grounds
separated. Bypass both the digital and analog VDD pins to
their respective grounds with a ceramic 0.1µF capacitor
close to the input pin. A larger capacitor (1µF to 10µF)
should be placed somewhere on the PC board for low
frequency decoupling of both analog and digital supplies.
Therefore, if the sample clock frequency is 20MHz, the
internal calibration cycle is:
tInternal Cal Cycle = (7 x 228)/20 x 106 = 93.95s.
It should be noted that this method of periodic calibration
may not be acceptable if the fixing of the lower five output
bits during the calibration (see the discussion below on
external calibration pulse input function) would cause
problems since the calibration is executed asynchronously
without regard to the analog input signal.
The analog supply should be present before the digital
supply to reduce the risk of latch-up. The digital supply can
run from +3.3V or +5V. A +3.3V supply generates less
radiated noise at the digital outputs, but results in less drive
capability. The specifications do not change with digital
supply levels. Remember, the digital outputs will only swing
to DV DD .
External Calibration Pulse Input Function
If the auto calibration pulse generation function cannot be
used then periodic calibration can be performed by providing
externally input calibration pulses to the CAL input pin
(pin 41) and setting the SEL control input pin (pin 17) low.
Refer to Figure 3, External Calibration Pulse Timing
Diagram, for details on the required timing of the externally
supplied calibration pulses.
To obtain full expected performance from the converter be
sure that the circuit board has a large ground plane to
provide as low an impedance as possible. It is
recommended that the converter be mounted directly to the
A setup time of 10ns or longer is required for the CAL input
and it must stay low for at least one sample clock (CLK)
period. Calibration starts when the falling edge of the
externally supplied calibration pulse, input to the CAL pin, is
detected. One calibration is completed in 11 sample clock
cycles. Seven sample clock cycles after the falling edge of
the externally supplied calibration pulse is detected, the
calibration circuit takes exclusive possession of the lower
comparators, D0 through D4, for four sample clock cycles.
During this time, the D0 through D4 outputs are latched with
the previous data (cycle seven data). The upper 5 bits, D5
through D9, will operate as usual during the calibration.
The calibration must be done when the part is first powered
up, if the sampling frequency changes, when the supplies
vary more than 100mV or when (VRT - VRB) changes more
than 200mV. Figure 4 shows several possible external
calibration pulse timing schemes where the calibration is
performed outside the active video interval by using the
video sync signal as the externally supplied CAL input. It is
not necessary to calibrate as often as these figures show,
these are only design ideas. It is also possible to use only
the power-up calibration function by leaving the SEL control
input pin (pin 17) low and fixing the CAL input pin (pin 41)
either high or low. Note, however, that using only the powerup calibration function will require the above restrictions on
the sample frequency and the fluctuation range of the power
supply voltage and the reference voltage differential be
maintained.
15
HI5710A
circuit board and the use of a socket is highly discouraged.
Test Circuits
+V
S2
-
S1: ON IF A < B
S2: ON IF A > B
S1
+
-V
A<B
A>B
COMPARATOR
VIN
10
DUT
HI5710A
“0”
DVM
A10
B10
A1
A0
B1
B0
10
BUFFER
“1”
10
CLK (20MHz)
CONTROLLER
000 • • • 00
TO
111 • • • 10
FIGURE 17. INTEGRAL AND DIFFERENTIAL NON-LINEARITY ERROR TEST CIRCUIT
4.0V
fC -1kHz
SCOPE
SG
2.0V
1
2
NTSC
SIGNAL
SOURCE
100
IRE
0
- 40
SG
(CW)
VIN
AMP
DUT
HI5710A
10
1
12-BIT
D/A
2
CLK
40 IRE
MODULATION
VECTOR
SCOPE
4V
DG
DP
BURST
2V
SYNC
fC
FIGURE 18. MAXIMUM OPERATIONAL SPEED AND DIFFERENTIAL GAIN /PHASE ERROR TEST CIRCUIT
4V
VDD
VRT
VIN
2V
4V
IOL
VIN
VRB
2V
CLK
GND
IOH
VRB
CLK
VOL
OE
VDD
VRT
VOH
OE
+
GND
-
FIGURE 19A.
FIGURE 19B.
FIGURE 19. DIGITAL OUTPUT TEST CIRCUIT
16
+
-
HI5710A
Test Circuits
(Continued)
AVDD
14-BIT
COUNTER
1
16
CLK
D
CO
CLR
AVDD
OUT
Q
CLR
SENCE
AMP 1
AVSS
VRT
24-BIT
COUNTER
SENCE
AMP 2
VRB
CO
CLR
RESET
SEL
CE
CAL
FIGURE 20. CALIBRATION PULSE GENERATION CIRCUIT
Typical Application Circuits
-
-
TSTR
AT
VIN
2.0V
NC
CAL
TS
AVSS
AVSS
+5VA
0.1
0.1µF
AVDD
AVDD
AVSS
VRT
AVSS
VRT
NC
NC
NC
VRB
36 35 34 33 32 31 30 29 28 27 26 25
24
23
39
22
40
21
41
20
42
19
HI5710A
43
18
CE
OE
CLK
MINV
TESTMODE
17
16
SEL
DVSS
NC
46
15
RESET
NC
DVSS
47
14
TIN
13
8 9 10 11 12
TO
1
2 3
4
5
6 7
+5VA
AVDD
45
48
CLOCK INPUT
LINV
44
DVDD
+3.3VD
37
38
VRB
0.1µF
4.0V
0.1µF
D9
D8
D6
D7
D5
D4
DVSS
D3
D2
AVSS
D0
D1
10µF
+5VA
+
AVss
2.0V
+
4.0V
+3.3VD
0.1
DIGITAL OUTPUTS
FIGURE 21A. POWER-UP CALIBRATION WITH INTERNAL AUTO CALIBRATION SELECTED
17
DVSS
10µF
HI5710A
Typical Application Circuits
(Continued)
-
-
TSTR
AT
VIN
2.0V
NC
CAL
CALIBRATION
PULSE
TS
AVSS
AVSS
+5VA
0.1
0.1µF
AVDD
AVDD
AVSS
VRT
AVSS
VRT
NC
NC
NC
VRB
36 35 34 33 32 31 30 29 28 27 26 25
24
23
39
40
22
21
41
20
42
19
HI5710A
43
18
CE
OE
CLK
MINV
TESTMODE
17
16
SEL
DVSS
NC
46
15
RESET
NC
DVSS
47
14
TIN
48
13
8 9 10 11 12
TO
2 3
4
5
6 7
+5VA
AVDD
45
1
CLOCK INPUT
LINV
44
DVDD
+3.3VD
37
38
VRB
0.1µF
4.0V
10µF
+5VA
+
AVss
2.0V
+
4.0V
0.1µF
DVSS
D9
D8
D6
D7
D5
D4
DVSS
D3
D2
D0
D1
AVSS
+3.3VD
0.1
DIGITAL OUTPUTS
FIGURE 21B. POWER-UP CALIBRATION WITH EXTERNAL CALIBRATION PULSE INPUT SELECTED
18
10µF
HI5710A
Typical Application Circuits
(Continued)
-
+
TSTR
AT
VIN
NC
CAL
TS
AVSS
AVSS
AVDD
AVDD
AVSS
VRT
AVSS
VRT
NC
NC
NC
VRB
VRB
40
21
41
20
42
19
HI5710A
43
18
OE
CLK
MINV
TESTMODE
16
46
15
RESET
NC
DVSS
47
14
TIN
48
13
8 9 10 11 12
TO
1
2 3
4
5
6 7
+5VA
AVDD
45
17
CLOCK INPUT
LINV
NC
44
0.1µF
D9
D8
D6
D7
AVSS
D0
D1
0.1µF
22
CE
SEL
DVSS
DVDD
+3.3VD
39
D5
0.1
23
D4
DVSS
+5VA
36 35 34 33 32 31 30 29 28 27 26 25
24
D3
2.0V
37
38
D2
4.0V
10µF
+5VA
0.1µF
AVss
2.0V
+
4.0V
+3.3VD
0.1
DIGITAL OUTPUTS
FIGURE 21C. ONLY POWER-UP CALIBRATION BEING UTILIZED
19
DVSS
10µF
Timing Definitions
Dynamic Performance Definitions
Sampling Delay, is the time delay between the external
sample command (the rising edge of the clock) and the time
at which the analog input signal is actually sampled. This
delay is due to internal clock path propagation delays.
Fast Fourier Transform (FFT) techniques are used to
evaluate the dynamic performance of the HI5710A. A low
distortion sine wave is applied to the input, it is sampled, and
the output is stored in RAM. The data is then transformed
into the frequency domain with a 2048 point FFT and
analyzed to evaluate the dynamic performance of the A/D.
The analog sine wave input signal to the converter is -0.5dB
down from full scale for all these tests. The distortion
numbers are quoted in dBc (decibels with respect to carrier)
and DO NOT include any correction factors for normalizing
to full scale.
Data Latency, after the analog sample is taken, the digital
representation is output on the digital data output bus after
the 3rd cycle of the clock. This is due to the pipeline nature
of the converter where the data has to ripple through the
stages. This delay is specified as the data latency. After the
data latency time, the data representing each succeeding
analog input sample is output on the following rising edge of
the clock pulse. The digital data output lags the analog input
sample by 3 sampling clock cycles.
Signal-to-Noise Ratio, SNR, is the measured RMS signal to
RMS noise for a specified analog input frequency and
sampling frequency. The noise is the RMS sum of all of the
spectral components excluding the fundamental and the first
five harmonics.
Power-up Initialization, this time is defined as the
maximum number of clock cycles that are required to
initialize the converter at power-up. The requirement arises
from the need to initialize some dynamic circuits within the
converter.
Signal-to-Noise + Distortion Ratio, SINAD, is the measured
RMS signal to RMS sum of all other spectral components
below the Nyquist frequency excluding DC.
Static Performance Definitions
Effective Number Of Bits, ENOB, the effective number of
bits (ENOB) is calculated from the measured SINAD data. as
follows:
Differential Linearity Error, DNL, is the worst case
deviation of a code width from the ideal value of 1 LSB. The
converter is guaranteed to have no missing codes over the
operating temperature range.
ENOB = (SINAD - 1.76 + V CORR) / 6.02,
where: VCORR = 0.5dB.
Integral Linearity Error, INL, is the worst case deviation of
a code center from a best fit straight line calculated from the
measured data.
VCORR adjusts the ENOB for the amount the analog input
signal is below full scale.
2nd and 3rd Harmonic Distortion, is the ratio of the RMS
value of the 2nd and 3rd harmonic component, respectively,
to the RMS value of the measured input signal.
Analog Input Bandwidth, is the frequency at which the
amplitude of the digitally reconstructed output has
decreased 3dB below the amplitude of the input sine wave.
The input sine wave has a peak-to-peak amplitude equal to
the differential reference voltage. The bandwidth given is
measured at the specified sampling frequency.
20
AMP
HFA1135
HFA1245
HA5020
HFA1135:
HFA1245:
HA5020:
HI5710A:
HI5767/2/4:
HSP9501:
HSP48410:
HSP48908:
HSP48212:
HSP43891:
HSP43168:
HSP43216:
HI1171:
HI3338:
HI3050:
HA2842:
HFA1115:
A/D
HI5710A
HI5767/2
HI5767/4
DSP/µP
HSP9501
HSP48410
HSP48908
HSP48212
HSP43891
HSP43168
HSP43216
D/A
HI1171
HI3050
HI3338
AMP
HA5020
HA2842
HFA1115
350MHz Op Amp with Output Limiting
Dual 350MHz Op Amp with Disable/Enable
100MHz Video Op Amp
10-Bit, 20 MSPS, A/D Converter
10-Bit, 20/40 MSPS, Low Power A/D Converter with Internal Reference
Programmable Data Buffer
Histogrammer/Accumulating Buffer, 10-Bit Pixel Resolution
2-D Convolver, 3 x 3 Kernal Convolution, 8-Bit
Digital Video Mixer
Digital Filter, 30MHz, 9-Bit
Dual FIR Filter, 10-Bit, 33MHz/45MHz
Digital Half Band Filter
8-Bit, 40MHz, Video D/A Converter
8-Bit, 50MHz, Video D/A Converter
Triple 10-Bit, 50MHz, Video DAC
High Output Current, Video Op Amp
350MHz Programmable Gain Buffer with Output Limiting
CMOS Logic Available in HC, HCT, AC, ACT, and FCT.
FIGURE 22. 10-BIT VIDEO IMAGING COMPONENTS
AMP
HFA3600
HFA3102
HFA3101
HFA1100
HFA3600:
HFA3102:
HFA3101:
HFA1100:
HI5710A:
HI5767/2/4:
HSP43168:
HSP43216:
HSP43891:
HSP50016:
HSP50110:
HSP50210:
HI5721:
HI5780:
HI20201:
HI20203:
HFA1115:
A/D
HI5710A
HI5767/2
HI5767/4
DSP/µP
HSP43168
HSP43216
HSP43891
HSP50016
HSP50110
HSP50210
D/A
HI5721
HI20201
HI20203
HI5780
AMP
HFA1115
Low Noise Amplifier/Mixer
Dual Long-Tailed Pair Transistor Array
Gilbert Cell Transistor Array
850MHz Op Amp
10-Bit, 20 MSPS, A/D Converter
10-Bit, 20/40 MSPS, Low Power A/D Converter with Internal Reference
Dual FIR Filter, 10-Bit, 33MHz/45MHz
Digital Half Band Filter
Digital Filter, 30MHz, 9-Bit
Digital Down Converter
Digital Quadrature Tuner
Digital Costas Loop
10-Bit, 100MHz, Communications D/A Converter
10-Bit, 80MHz CMOS D/A Converter
10-Bit, 160MHz, High Speed D/A Converter
8-Bit, 160MHz, High Speed D/A Converter
350MHz Programmable Gain Buffer with Output Limiting
CMOS Logic Available in HC, HCT, AC, ACT, and FCT.
FIGURE 23. 10-BIT COMMUNICATIONS COMPONENTS
21