NSC ADC1175

ADC1175-50
8-Bit, 50 MSPS, 125 mW A/D Converter
General Description
Features
The ADC1175-50 is a low power, 50 MSPS analog-to-digital
converter that digitizes signals to 8 bits while consuming just
125 mW (typ). The ADC1175-50 uses a unique architecture
that achieves 6.8 Effective Bits at 25 MHz input and 50 MHz
clock frequency. Output formatting is straight binary coding.
The excellent DC and AC characteristics of this device, together with its low power consumption and +5V single supply
operation, make it ideally suited for many video and imaging
applications, including use in portable equipment. Furthermore, the ADC1175-50 is resistant to latch-up and the outputs
are short-circuit proof. The top and bottom of the
ADC1175-50's reference ladder is available for connections,
enabling a wide range of input possibilities. The low input capacitance (7 pF, typical) makes this device easier to drive than
conventional flash converters and the power down mode reduces power consumption to less than 5 mW.
The ADC1175-50 is offered in TSSOP and is designed to operate over the extended commercial temperature range of
−20°C to +75°C.
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Internal Track-and-Hold function
Single +5V operation
Internal reference bias resistors
Industry standard pinout
Power-down mode (<5 mW)
Key Specifications
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Resolution
8 Bits
Maximum Sampling Frequency
50 MSPS (min)
THD
54 dB (typ)
DNL
0.7 LSB (typ)
ENOB @ fIN = 25 MHz
6.8 Bits (typ)
Guaranteed No Missing Codes
Power Consumption (Excluding Ref- 125 mW (typ), 190
erence Current)
mW (max)
Applications
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Digital Still Cameras
CCD Imaging
Electro-Optics
Video Digitization
Multimedia
Connection Diagrams
24-pin SOIC and TSSOP
24-pin LLP (CSP)
10089634
10089601
Top View
SOIC obsolete. Shown for reference only
Bottom View
TRI-STATE® is a registered trademark of National Semiconductor Corporation.
© 2007 National Semiconductor Corporation
100896
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ADC1175-50 8-Bit, 50 MSPS, 125 mW A/D Converter
September 2007
ADC1175-50
Ordering Information
Order Code
Temperature Range
Description
ADC1175-50CIJM *
−20°C to +70°C
SOIC (EIAJ)
ADC1175-50CIJMX *
−20°C to +70°C
SOIC (EIAJ) tape and reel
ADC1175-50CIMT
−20°C to +70°C
TSSOP
ADC1175-50CIMTX
−20°C to +70°C
TSSOP (tape and reel)
ADC1175-50CILQ *
−20°C to +70°C
LLP tape and reel (1,000 units)
ADC1175-50CILQX *
−20°C to +70°C
LLP tape and reel (4,500 units)
ADC1175-50EVAL *
Evaluation Board
Obsolete in the SOIC (EIAJ) and LLP packages. The Evaluation Board is also discontinued. Shown for reference only.
Block Diagram
10089602
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2
ADC1175-50
Pin Descriptions and Equivalent Circuits
(LLP pins in parentheses)
Pin
No.
Symbol
19
(17)
VIN
16
(14)
VRTS
Reference Top Bias with internal pull up resistor. Short this
pin to VRT to self-bias the reference ladder.
VRT
Analog input that is the high (top) side of the reference
ladder of the ADC. Voltages on VRT and VRB inputs define
the VIN conversion range. Bypass well. See Section 2.0 for
more information.
23
(21)
VRB
Analog input that is the low (bottom) side of the reference
ladder of the ADC. Nominal range is 0.0V to 4.0V, with
optimized value of 0.6V. Voltage on VRT and VRB inputs
define the VIN conversion range. Bypass well. See Section
2.0 for more information.
22
(20)
VRBS
Reference Bottom Bias with internal pull down resistor.
Short to VRB to self-bias the reference ladder. Bypass well
(unless grounded). See Section 2.0 for more information.
PD
CMOS/TTL compatible Digital input that, when high, puts
the ADC1175-50 into a power-down mode where total
power consumption is typically less than 5 mW. With this
pin low, the device is in the normal operating mode.
17
(15)
1
(23)
Equivalent Circuit
Description
Analog signal input. Conversion range is VRT to VRB.
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ADC1175-50
Pin
No.
Symbol
12
(10)
CLK
CMOS/TTL compatible digital clock input. VIN is sampled on
the falling edge of CLK input.
D0–D7
Conversion data digital Output pins. D0 is the LSB, D7 is
the MSB. Valid data is output just after the rising edge of
the CLK input. These pins are in a high impedance mode
when the PD pin is low.
11, 13,
14
(9, 11,
12)
DVDD
Positive digital supply pin. Connect to a quiet voltage source
of +5V. AVDD and DVDD should have a common source and
be separately bypassed with a 10 µF capacitor and a 0.1
µF ceramic chip capacitor. See Section 4.0 for more
information.
2, 24
(22, 24)
DVSS
The ground return for the digital supply. AVSS and DVSS
should be connected together close to the ADC1175-50.
15, 18
(13, 16)
AVDD
Positive analog supply pin. Connect to a quiet voltage
source of +5V. AVDD and DVDD should have a common
source and be separately bypassed with a 10 µF capacitor
and a 0.1 µF ceramic chip capacitor. See Section 4.0 for
more information.
20, 21
(18, 19)
AVSS
The ground return for the analog supply. AVSS and DVSS
should be connected together close to the ADC1175-50
package.
3 thru 10
(1 thru 8)
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Equivalent Circuit
Description
4
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
Supply Voltage (AVDD, DVDD)
Voltage on Any Input or Output Pin
Reference Voltage (VRT, VRB)
CLK, PD Voltage Range
Digital Output Voltage (VOH, VOL)
Input Current at Any Pin (Note 3)
Package Input Current (Note 3)
Power Dissipation at TA = 25°C
ESD Susceptibility (Note 5)
Human Body Model
Machine Model
Soldering Temperature, Infrared,
(10 sec.) (Note 6)
Storage Temperature
Short Circuit Duration
(Single High Output to Ground)
(Notes 1, 2)
Operating Temperature Range
−20°C ≤ TA ≤ +75°C
Supply Voltage (AVDD, DVDD)
AVDD − DVDD
Ground Difference |DVSS – AVSS|
Pin 11 to Pin 13 Voltage
Upper Reference Voltage (VRT)
Lower Reference Voltage (VRB)
VRT - VRB
VIN Voltage Range
6.5V
−0.3V to +6.5V
AVSS to VDD
−0.5 to (AVDD +0.5V)
VSS to VDD
±25 mA
±50 mA
See (Note 4)
+4.75V to +5.25V
<0.5V
0V to 100 mV
<0.5V
1.0V to VDD
0V to 4.0V
1V to 2.8V
VRB to VRT
Package Thermal Resistance
2000V
250V
235°C
−65°C to +150°C
Package
θJA
TSSOP-24
LLP-24
92°C / W
40°C / W
1 Second
Converter Electrical Characteristics
The following specifications apply for AVDD = DVDD = +5.0 VDC, PD = 0V, VRT = +2.6V, VRB = 0.6V, CL = 20 pF, fCLK = 50 MHz at
50% duty cycle. Boldface limits apply for TA = TMIN to TMAX; all other limits TA = 25°C (Notes 7, 8).
Symbol
Parameter
Conditions
Typical
(Note 9)
Limits
(Note 9)
Units
(Limits)
±0.8
±1.95
LSB (max)
+0.7
+1.75
LSB (max)
−0.7
−1.0
LSB (min)
8
Bits
DC ACCURACY
INL
DNL
Integral Non Linearity Error
Differential Non-Linearity
VIN = 0.6V to 2.6V
VIN = 0.6V to 2.6V
Resolution for No Missing
Codes
EOT
Top Offset Voltage
−12
mV
EOB
Bottom Offset Voltage
+10
mV
VIDEO ACCURACY
DP
Differential Phase Error
fIN = 4.43 MHz Modulated Ramp
0.5
deg
DG
Differential Gain Error
fIN = 4.43 MHz Modulated Ramp
1.0
%
ANALOG INPUT AND REFERENCE CHARACTERISTIC
VIN
Input Range
CIN
VIN Input Capacitance
RIN
2.0
VRB
V (min)
VRT
V (max)
(CLK LOW)
4
(CLK HIGH)
7
pF
RIN Input Resistance
>1
MΩ
BW
Full Power Bandwidth
120
MHz
RRT
Top Reference Resistor
320
Ω
RREF
Reference Ladder Resistance VRT to VRB
270
RRB
Bottom Reference Resistor
80
VIN = 1.5V
+0.7 Vrms
VRT = VRTS, VRB = VRBS
IREF
7
Reference Ladder Current
VRT = VRTS, VRB = AVSS
5
8
pF
200
350
Ω (min)
Ω (max)
5.4
mA (min)
10.8
mA (max)
6.1
mA (min)
12.3
mA (max)
Ω
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ADC1175-50
Operating Ratings
Absolute Maximum Ratings (Notes 1, 2)
ADC1175-50
Symbol
Parameter
Conditions
Typical
(Note 9)
Limits
(Note 9)
Units
(Limits)
VRT
Reference Top Self Bias
Voltage
VRT Connected to VRTS,
VRB Connected to VRBS
2.6
VRB
Reference Bottom Self Bias
Voltage
VRT Connected to VRTS,
VRB Connected to VRBS
0.6
0.55
0.70
V (min)
V (max)
VRT Connected to VRTS,
VRB Connected to VRBS
2
1.89
2.20
(V (min)
V (max)
VRT Connected to VRTS,
VRB Connected to AVSS
2.3
VRTS –
VRBS
Self Bias Voltage Delta
VRT – VRB
Reference Voltage Differential
V (min)
V (max)
V
2
1.0
2.8
V (min)
V (max)
fIN = 4.4 MHz, fCLK = 40 MHz
7.2
6.7
Bits (min)
fIN = 19.9 MHz, fCLK = 40 MHz
7.0
6.4
Bits (min)
fIN = 1.3 MHz, fCLK = 50 MHz
7.3
Bits
fIN = 4.4 MHz, fCLK = 50 MHz
7.2
Bits
fIN = 24.9 MHz, fCLK = 50 MHz
6.8
6.1
Bits (min)
fIN = 4.4 MHz, fCLK = 40 MHz
45
42
dB (min)
fIN = 19.9 MHz, fCLK = 40 MHz
44
40
dB (min)
fIN = 1.3 MHz, fCLK = 50 MHz
46
fIN = 4.4 MHz, fCLK = 50 MHz
45
fIN = 24.9 MHz, fCLK = 50 MHz
43
38.4
dB (min)
fIN = 4.4 MHz, fCLK = 40 MHz
46
42.5
dB (min)
fIN = 19.9 MHz, fCLK = 40 MHz
44
41
dB (min)
fIN = 1.3 MHz, fCLK = 50 MHz
48
fIN = 4.4 MHz, fCLK = 50 MHz
45
fIN = 24.9 MHz, fCLK = 50 MHz
44
fIN = 1.3 MHz
57
dB
Spurious Free Dynamic Range fIN = 4.4 MHz
CONVERTER DYNAMIC CHARACTERISTICS
ENOB
SINAD
SNR
SFDR
THD
Effective Number of Bits
Signal-to-Noise & Distortion
Signal-to-Noise Ratio
Total Harmonic Distortion
dB
dB
dB
dB
40
dB (min)
56
dB
fIN = 24.9 MHz
51
dB
fIN = 1.3 MHz
−55
dB
fIN = 4.4 MHz
−54
dB
fIN = 24.9 MHz
−51
dB
POWER SUPPLY CHARACTERISTICS
IADD
Analog Supply Current
DVDD = AVDD = 5.25V
13
mA
IDDD
Digital Supply Current
DVDD = AVDD = 5.25V
11
mA
DVDD = AVDD = 5.25V, fCLK = 50 MHz
25
DVDD = AVDD = 5.25V, CLK Inactive (low)
14
IADD + IDDD Total Operating Current
Power Consumption
PD pin low
125
Power Consumption
PD pin high
<5 mW
36
mA (max)
mA
190
mW (max)
mW
CLK, PD DIGITAL INPUT CHARACTERISTICS
VIH
Logical High Input Voltage
2.0
V (min)
VIL
Logical Low Input Voltage
0.8
V (max)
IIH
Logical High Input Current
VIH = DVDD = AVDD = +5.25V
±5
µA (max)
IIL
Logical Low Input Current
VIL = 0V, DVDD = AVDD = +5.25V
±5
µA (max)
CIN
Digital Input Capacitance
4
pF
DIGITAL OUTPUT CHARACTERISTICS
IOH
Output Current, Logic HIGH
DVDD = 4.75V, VOH = 4.0V
−1.1
mA (min)
IOL
Output Current, Logic LOW
DVDD = 4.75V, VOL = 0.4V
1.8
mA (min)
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IOZH, IOZL
Parameter
TRI-STATE® Output Current
Typical
(Note 9)
Conditions
DVDD = 5.25V, PD = DVDD,
VOL = DVDD, or VOL = 0V
Limits
(Note 9)
±20
Units
(Limits)
µA
AC ELECTRICAL CHARACTERISTICS
fC1
Maximum Conversion Rate
55
fC2
Minimum Conversion Rate
1
tOD
Output Delay
CLK high to data valid
14
Pipeline Delay (Latency)
CLK low to acquisition of data
50
MHz (min)
5
ns (min)
MHz
20
ns (max)
2.5
Clock Cycles
3
ns
tDS
Sampling (Aperture) Delay
tAJ
Aperture Jitter
10
ps rms
tOH
Output Hold Time
CLK high to data invalid
10
ns
tEN
PD Low to Data Valid
Loaded as in Figure 2
140
ns
Note 1: “Absolute Maximum Ratings” indicate limits beyond which damage to the device may occur. Operating Ratings indicate conditions for which the device
is functional, but do not guarantee specific performance limits. For guaranteed specifications and test conditions, see the Electrical Characteristics. The guaranteed
specifications apply only for the test conditions listed. Some performance characteristics may degrade when the device is not operated under the listed test
conditions.
Note 2: All voltages are measured with respect to GND = AVSS = DVSS = 0V, unless otherwise specified.
Note 3: When the input voltage at any pin exceeds the power supplies (that is, less than AVSS or DVSS, or greater than AVDD or DVDD), the current at that pin
should be limited to 25 mA. The 50 mA maximum package input current rating limits the number of pins that can safely exceed the power supplies with an input
current of 25 mA to two.
Note 4: The absolute maximum junction temperature (TJ max) for this device is 150°C. The maximum allowable power dissipation is dictated by TJ max, the
junction-to-ambient thermal resistance (θJA) and the ambient temperature (TA), and can be calculated using the formula PD max = (TJ max – TA)/θJA. The values
for maximum power dissipation listed above will be reached only when the ADC1175-50 is operated in a severe fault condition (e.g., when input or output pins
are driven beyond the power supply voltages, or the power supply polarity is reversed). Obviously, such conditions should always be avoided.
Note 5: Human body model is 100 pF capacitor discharged through a 1.5 kΩ resistor. Machine model is 220 pF discharged through 0Ω.
Note 6: See AN-450, “Surface Mounting Methods and Their Effect on Product Reliability”, or the section entitled “Surface Mount” found in any post 1986 National
Semiconductor Linear Data Book for other methods of soldering surface mount devices.
Note 7: The analog inputs are protected as shown below. Input voltage magnitudes up to 6.5V or 500 mV below GND will not damage this device. However,
errors in the A/D conversion can occur if the input goes above VDD or below GND by more than 50 mV. As an example, if AVDD is 4.75 VDC, the full-scale input
voltage must be ≤4.80 VDC to ensure accurate conversions.
10089610
Note 8: To guarantee accuracy, it is required that AVDD and DVDD be well bypassed. Each VDD pin must be decoupled with separate bypass capacitors.
Note 9: Typical figures are at TJ = 25°C, and represent most likely parametric norms. Test limits are guaranteed to National's AOQL (Average Outgoing Quality
Level).
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ADC1175-50
Symbol
ADC1175-50
Typical Performance Characteristics
AVDD = DVDD = 5V, fCLK = 50 MHz, unless otherwise stated.
INL Plot
DNL Plot
10089612
10089611
INL vs. Temperature
DNL vs. Temperature
10089613
10089614
SNR vs. Temp & fIN
THD vs. Temp & fIN
10089616
10089615
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8
ADC1175-50
SINAD & ENOB vs. Temp & fIN
SINAD & ENOB vs. Clock
Duty Cycle
10089617
10089618
SFDR vs. Temp & fIN
tOD vs. Temperature
10089619
10089620
Power Supply Current vs. fCLK
Spectral Response
10089622
10089621
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ADC1175-50
Specification Definitions
ANALOG INPUT BANDWIDTH is a measure of the frequency at which the reconstructed output fundamental drops 3 dB
below its low frequency value for a full scale input. The test is
performed with fIN equal to 100 kHz plus integer multiples of
fCLK. The input frequency at which the output is −3 dB relative
to the low frequency input signal is the full power bandwidth.
APERTURE JITTER is the time uncertainty of the sampling
point (tDS), or the range of variation in the sampling delay.
BOTTOM OFFSET is the difference between the input voltage that just causes the output code to transition to the first
code and the negative reference voltage. Bottom Offset is
defined as EOB = VZT − VRB, where VZT is the first code transition input voltage. Note that this is different from the normal
Zero Scale Error.
DIFFERENTIAL GAIN ERROR is the percentage difference
between the output amplitudes of a high frequency reconstructed sine wave at two different d.c. levels.
DIFFERENTIAL NON-LINEARITY (DNL) is the measure of
the maximum deviation from the ideal step size of 1 LSB. DNL
is measured at the rated clock frequency with a ramp input.
DIFFERENTIAL PHASE ERROR is the difference in the output phase of a reconstructed small signal sine wave at two
different d.c. levels.
EFFECTIVE NUMBER OF BITS (ENOB, or EFFECTIVE
BITS) is another method of specifying Signal-to-Noise and
Distortion Ratio, or SINAD. ENOB is defined as (SINAD −
1.76) / 6.02 and says that the converter is equivalent to a perfect ADC of this (ENOB) number of bits.
INTEGRAL NON-LINEARITY (INL) is a measure of the deviation of each individual codes from a line drawn from zero
scale (1/2 LSB below the first code transition) through positive
full scale (1/2 LSB above the last code transition). The deviation of any given code from this straight line is measured
from the center of that code value. The end point test method
is used. INL is measured at rated clock frequency with a ramp
input.
OUTPUT DELAY is the time delay after the rising edge of the
input clock before the data update is present at the output
pins.
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OUTPUT HOLD TIME is the length of time that the output data
is valid after the rise of the input clock.
PIPELINE DELAY (LATENCY) is the number of clock cycles
between initiation of conversion and when that data is presented to the output stage. Data for any given sample is
available the Pipeline Delay plus the Output Delay after that
sample is taken. New data is available at every clock cycle,
but the data lags the conversion by the pipeline delay.
SAMPLING (APERTURE) DELAY, or tDS, is the time required after the falling edge of the clock for the sampling
switch to open (in other words, for the Sample/Hold circuit to
go from the “sample” mode into the “hold” mode). The Sample/Hold circuit effectively stops capturing the input signal and
goes into the “hold” mode tDS after the clock goes low.
SIGNAL TO NOISE RATIO (SNR) is the ratio of the rms value
of the input signal to the rms value of the other spectral components below one-half the sampling frequency, not including
harmonics or d.c.
SIGNAL TO NOISE PLUS DISTORTION (S/(N+D) or
SINAD) is the ratio of the rms value of the input signal to the
rms value of all of the other spectral components below half
the clock frequency, including harmonics but excluding d.c.
SPURIOUS FREE DYNAMIC RANGE (SFDR) is the difference, expressed in dB, between the rms values of the input
signal and the peak spurious signal, where a spurious signal
is any signal present in the output spectrum that is not present
at the input.
TOP OFFSET is the difference between the positive reference voltage and the input voltage that just causes the output
code to transition to full scale and is defined as EOT = VFT −
VRT. Where VFT is the full scale transition input voltage. Note
that this is different from the normal Full Scale Error.
TOTAL HARMONIC DISTORTION (THD) is the ratio of the
rms total of the first six harmonic components to the rms value
of the input signal.
10
ADC1175-50
Timing Diagram
10089623
FIGURE 1. ADC1175-50 Timing Diagram
10089624
FIGURE 2. tEN, tDIS Test Circuit
11
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ADC1175-50
cally less than 5 mW. When the part is powered down, the
digital output pins are in a high impedance TRI-STATE. It
takes about 140 ns for the part to become active upon coming
out of the power down mode.
Functional Description
The ADC1175-50 maintains superior dynamic performance
with input frequencies up to 1/2 the clock frequency, achieving
6.8 effective bits with a 50 MHz sampling rate and 25 MHz
input frequency.
The analog signal at VIN that is within the voltage range set
by VRT and VRB are digitized to eight bits at up to 55 MSPS.
Input voltages below VRB will cause the output word to consist
of all zeroes. Input voltages above VRT will cause the output
word to consist of all ones. While the ADC1175-50 is specified
for top and bottom reference voltages (VRT and VRB) or 2.6V
and 0.6V, respectively, and will give best performance at
these values, VRT has a range of 1.0V to the analog supply
voltage, AVDD, while VRB has a range of 0V to 4.0V. VRT
should always be at least 1.0V more positive than VRB. With
VRT voltages above 2.8V, it is necessary to reduce the clock
frequency to maintain SINAD performance. VRT should always be between 1.0V and 2.8V more positive than VRB.
If VRT and VRTS are connected together and VRB and VRBS are
connected together, the nominal values of VRT and VRB are
2.6V and 0.6V, respectively. If VRT and VRTS are connected
together and VRB is grounded, the nominal value of VRT is
2.3V.
Data is acquired at the falling edge of the clock and the digital
equivalent of that data is available at the digital outputs 2.5
clock cycles plus tOD later. The ADC1175-50 will convert as
long as the clock signal is present at the CLK pin. The PD pin,
when high, puts the device into the Power Down mode. When
the PD pin is low, the device is in the normal operating mode.
The Power Down pin (PD), when high, puts the ADC1175-50
into a power down mode where power consumption is typi-
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Applications Information
(All Schematic pin numbers refer to the TSSOP.)
1.0 THE ANALOG INPUT
The analog input of the ADC1175-50 is a switch followed by
an integrator. That is, a switched capacitor input, appearing
as 4 pF when the clock is low, and 7 pF when the clock is high.
Switched capacitor inputs produce voltage spikes at the input
pin at the ADC sample rate. There should be no attempt to
eliminate these spikes, but they should settle out during the
sample period (the clock high time). An RC at the ADC analog
input pin, as shown in Figure 3, will help. For Nyquist applications, the capacitor should be about 10 times ADC track
mode input capacitance and the pole frequency of this RC
should be about the ADC sample rate. The LMH6702, and the
LMH6609 have been found to be excellent amplifiers for driving the ADC1175-50. Do not drive the input beyond the supply
rails. Figure 3 shows an example of an input circuit using the
LMH6702.
Driving the analog input with input signals up to 2.8 VP-P will
result in normal behavior where signals above VRT will result
in a code of FFh and input voltages below VRB will result in an
output code of zero. Input signals above 2.8 VP-P may result
in odd behavior where the output code is not FFh when the
input exceeds VRT.
12
ADC1175-50
10089625
FIGURE 3. Driving the ADC1175-50. Choose an op-amp that can drive a dynamic capacitance.
13
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ADC1175-50
needed for these amplifiers if the lower one is required to go
slightly negative to force the required reference voltage.
If reference voltages are desired that are more than a few tens
of millivolts from the self-bias values, the circuit of Figure 5
will allow forcing the reference voltages to whatever levels are
desired. This circuit provides the best performance because
of the low source impedance of the transistors. Note that the
VRTS and VRBS pins are left floating.
To minimize noise effects and ensure accurate conversions,
the total reference voltage range (VRT − VRB) should be a
minimum of 1.0V and a maximum of about 2.8V.
The ADC1175-50 is designed to operate with top and bottom
references of 2.6V and 0.6V, respectively. However, it will
function with reduced performance with a top reference voltage as high as AVDD and a bottom reference voltage as low
as ground.
If reference voltages are desired that are more than a few tens
of millivolts from the self-bias values, the circuit of Figure 5
will allow forcing the reference voltages to whatever levels are
desired. This circuit provides the best performance because
of the low source impedance of the transistors. Note that the
VRTS and VRBS pins are left floating.
VRT can be anywhere between VRB + 1.0V and the analog
supply voltage, and VRB can be anywhere between ground
and 1.0V below VRT. To minimize noise effects and ensure
accurate conversions, the total reference voltage range (VRT
- VRB) should be a minimum of 1.0V and a maximum of about
2.8V. If VRB is not required to be below about +700mV, the
-5V points in Figure 5 can be returned to ground and the negative supply eliminated.
2.0 REFERENCE INPUTS
The reference inputs VRT (Reference Top) and VRB (Reference Bottom) are the top and bottom of the reference ladder.
Input signals between these two voltages will be digitized to
8 bits. External voltages applied to the reference input pins
should be within the range specified in the Operating Ratings
table (1.0V to AVDD for VRT and 0V to (AVDD − 1.0V) for
VRB). Any device used to drive the reference pins should be
able to source sufficient current into the VRT pin and sink sufficient current from the VRB pin.
The reference ladder can be self-biased by connecting VRT to
VRTS and connecting the VRB to VRBS to provide top and bottom reference voltages of approximately 2.6V and 0.6V, respectively, with VCC = 5.0V. This connection is shown in
Figure 3. If VRT and VRTS are tied together, but VRB is tied to
analog ground, a top reference voltage of approximately 2.3V
is generated. The top and bottom of the ladder should be bypassed with 10 µF tantalum capacitors located close to the
reference pins.
The reference self-bias circuit of Figure 3 is very simple and
performance is adequate for many applications. Better linearity performance can generally be achieved by driving the
reference pins with a low impedance source.
By forcing a little current into or out of the top and bottom of
the ladder, as shown in Figure 4, the top and bottom reference
voltages can be trimmed and performance improved over the
self-bias method of Figure 3. The resistive divider at the amplifier inputs can be replaced with potentiometers, if desired.
The LMC662 amplifier shown was chosen for its low offset
voltage and low cost. Note that a negative power supply is
10089626
FIGURE 4. Better Defining the ADC Reference Voltage. Self bias is still used, but the reference voltages are trimmed by
providing a small trim current with the operational amplifiers.
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14
ADC1175-50
10089627
FIGURE 5. Driving the Reference to Force Desired Values requires driving with a low impedance source, provided by the
transistors. Note that pins 16 and 22 are not connected.
No pin should ever have a voltage on it that is in excess of the
supply voltage or below ground, not even on a transient basis.
This can be a problem upon application of power to a circuit.
Be sure that the supplies to circuits driving the CLK, PD, analog input and reference pins do not come up any faster than
does the voltage at the ADC1175-50 power pins.
Pins 11 and 13 are both labeled DVDD. Pin 11 is the supply
point for the digital core of the ADC, where pin 13 is used only
to provide power to the ADC output drivers. As such, pin 11
may be connected to a voltage source that is less than the
+5V used for AVDD and DVDD to ease interfacing to low voltage devices. Pin 11 should never exceed the pin 13 potential
by more than 0.5V.
3.0 OUTPUT DATA TIMING
The Output Delay (tOD) of the ADC1175-50 can be very close
to one half clock cycle. Because of this, the output data transition occurs very near the falling edge of the ADC clock. To
avoid clocking errors, you should use the rising edge of the
ADC clock to latch the output data of the ADC1175-50 and
not use the falling edge.
4.0 POWER SUPPLY CONSIDERATIONS
Many A/D converters draw sufficient transient current to corrupt their own power supplies if not adequately bypassed. A
10 µF tantalum or aluminum electrolytic capacitor should be
placed within an inch (2.5 centimeters) of the A/D power pins,
with a 0.1 µF ceramic chip capacitor placed as close as possible to the converter's power supply pins. Leadless chip
capacitors are preferred because they have low lead inductance.
While a single voltage source should be used for the analog
and digital supplies of the ADC1175-50, these supply pins
should be isolated from each other to prevent any digital noise
from being coupled to the analog power pins. We recommended a wide band choke, such as the JW Miller
FB20010-3B, be used between the analog and digital supply
lines, with a ceramic capacitor close to the analog supply pin.
If a resistor is used in place of the choke, a maximum of
10Ω should be used.
The converter digital supply should not be the supply that is
used for other digital circuitry on the board. It should be the
same supply used for the A/D analog supply.
As with all high speed converters, the ADC1175-50 should be
assumed to have little a.c. power supply rejection, especially
when self biasing is used by connecting VRT and VRTS together.
5.0 THE ADC1175-50 CLOCK
Although the ADC1175-50 is tested and its performance is
guaranteed with a 50 MHz clock, it typically will function with
clock frequencies from 1 MHz to 55 MHz.
The clock should be one of low jitter and close to 50% duty
cycle.
6.0 LAYOUT AND GROUNDING
Proper grounding and proper routing of all signals is essential
to ensure accurate conversion. Separate analog and digital
ground planes that are connected beneath the ADC1175-50
may be used, but best EMI practices require a single ground
plane. However, it is important to keep analog signal lines
away from digital signal lines and away from power supply
currents. This latter requirement requires the careful separation and placement of power planes. The use of power traces
rather than one or more power planes is not recommended
as higher frequencies are not well filtered with lumped capacitances. To filter higher frequency noise components it is
15
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ADC1175-50
necessary to have sufficient capacitance between the power
and ground planes.
If separate analog and digital ground planes are used, the
analog and digital grounds may be in the same layer, but
should be separated from each other. If separate analog and
digital ground layers are used, they should never overlap
each other.
Capacitive coupling between a typically noisy digital ground
plane and the sensitive analog circuitry can lead to poor performance that may seem impossible to isolate and remedy.
The solution is to keep the analog circuitry well separated
from the digital circuitry.
Digital circuits create substantial supply and ground current
transients. The logic noise thus generated could have significant impact upon system noise performance. The best logic
family to use in systems with A/D converters is one which
employs non-saturating transistor designs, or has low noise
characteristics, such as the 74LS and the 74HC(T) families.
The worst noise generators are logic families that draw the
largest supply current transients during clock or signal edges,
like the 74F family. In general, slower logic families will produce less high frequency noise than do high speed logic
families.
Since digital switching transients are composed largely of
high frequency components, total ground plane copper
weight will have little effect upon the logic-generated noise.
This is because of the skin effect. Total surface area is more
important than is total ground plane volume.
An effective way to control ground noise is by using a single,
solid ground plane and splitting the power plane into analog
and digital areas and to have power and ground planes in
adjacent board layers. There should be no traces within either
the power or the ground layers of the board. The analog and
digital power planes should reside in the same board layer so
that they can not overlap each other. The analog and digital
power planes define the analog and digital areas of the board.
Mount digital components and run digital lines only in the digital areas of the board. Mount the analog components and run
analog lines only in the analog areas of the board. Be sure to
treat all digital lines greater that one inch for each nanosecond
of rise time as transmission lines. That is, they should be of
constant, controlled impedance, be properly terminated at the
source end and run from one point to another single point.
The back of the LLP package has a large metal area inside
the area bounded by the pins. This metal area is connected
to the die substrate (ground). This pad may be left floating if
desired. If it is connected to anything, it should be to ground
near the connection between analog and digital ground
planes. Soldering this metal pad to ground will help keep the
die cooler and could yield improved performance because of
the lower impedance between die and board grounds. However, a poor layout could compromise performance.
Generally, analog and digital lines should cross each other at
90° to avoid getting digital noise into the analog path. In high
frequency systems, however, avoid crossing analog and digital lines altogether. Clock lines should be isolated from ALL
other lines, analog AND digital. Even the generally accepted
90° crossing should be avoided as even a little coupling can
cause problems at high frequencies. Best performance at
high frequencies and at high resolution is obtained with a
straight signal path.
Be especially careful with the layout of inductors. Mutual inductance can change the characteristics of the circuit in which
they are used. Inductors should not be placed side by side
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with each other, not even with just a small part of their bodies
beside each other.
The analog input should be isolated from noisy signal traces
to avoid coupling of spurious signals into the input. Any external component (e.g., a filter capacitor) connected between
the converter's input and ground should be connected to a
very clean point in the ground plane.
7.0 DYNAMIC PERFORMANCE
The ADC1175-50 is a.c. tested and its dynamic performance
is guaranteed. To meet the published specifications, the clock
source driving the CLK input must be free of jitter. For best
a.c. performance, isolating the ADC clock from any digital circuitry should be done with adequate buffers, as with a clock
tree. See Figure 6.
10089629
FIGURE 6. Isolating the ADC Clock from Digital Circuitry
It is good practice to keep the ADC clock line as short as possible and to keep it well away from any other signals. Other
signals can introduce jitter into the clock signal.
8.0 COMMON APPLICATION PITFALLS
Driving the inputs (analog or digital) beyond the power
supply rails. For proper operation, all inputs should not go
more than 50 mV below the ground pins or 50 mV above the
supply pins. Exceeding these limits on even a transient basis
may cause faulty or erratic operation. It is not uncommon for
high speed digital circuits to exhibit undershoot that goes
more than a volt below ground due to improper termination.
A resistor of about 50Ω to 100Ω in series with the offending
digital input, located close to the signal source, will usually
eliminate the problem.
Care should be taken not to overdrive the inputs of the
ADC1175-50. Such practice may lead to conversion inaccuracies and even to device damage.
Attempting to drive a high capacitance digital data bus.
The more capacitance the output drivers have to charge for
each conversion, the more instantaneous digital current is required from DVDD and DGND. These large charging current
spikes can couple into the analog section, degrading dynamic
performance. Buffering the digital data outputs (with a
74AC541, for example) may be necessary if the data bus to
be driven is heavily loaded. Dynamic performance can also
be improved by adding 47Ω series resistors at each digital
output, reducing the energy coupled back into the converter
output pins.
Using an inadequate amplifier to drive the analog input.
As explained in Section 1.0, the ADC input is a switched capacitor one and there are voltage spikes present there. This
type if input is more difficult to drive than is a fixed capacitance, and should be considered when choosing a driving
16
shown in Figure 7 and Figure 8. The circuit of Figure 7 has a
cutoff of about 5.5 MHz and is suitable for input frequencies
of 1 MHz to 5 MHz. The circuit of Figure 8 has a cutoff of about
11 MHz and is suitable for input frequencies of 5 MHz to 10
MHz. These filters should be driven by a generator of 75Ω
source impedance and terminated with a 75Ω resistor.
Not considering the effect on a driven CMOS digital circuit(s) when the ADC1175-50 is in the power down
mode. Because the ADC1175-50 output goes into a high
impedance state when in the power down mode, any CMOS
device connected to these outputs will have their inputs floating when the ADC is in power down. Should the inputs of the
circuit being driven by the ADC digital outputs float to a level
near 2.5V, a CMOS device could exhibit relative large supply
currents as the input stage toggles rapidly. The solution is to
use pull-down resistors at the ADC outputs. The value of
these resistors is not critical, as long as they do not cause
excessive currents in the outputs of the ADC1175-50. Low
pull-down resistor values could result in degraded SNR and
SINAD performance of the ADC1175-50. Values between 5
kΩ and 10 kΩ should work well.
10089630
FIGURE 7. A 5.5 MHz Low Pass filter to eliminate harmonics at the signal input. Use with maximum input frequencies of
1 MHz to 5 MHz.
10089631
FIGURE 8. An 11 MHz Low Pass filter to eliminate harmonics at the signal input. Use with maximum input frequencies of
5 MHz to 10 MHz
17
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ADC1175-50
device. The LMH6702 and the LMH6609 have been found to
be an excellent device for driving the ADC1175-50. Also remember to use the RC between the driving source and the
ADC input, as explained in Section 1.0.
Driving the VRT pin or the VRB pin with devices that can
not source or sink the current required by the ladder. As
mentioned in Section 2.0, care should be taken to see that
any driving devices can source sufficient current into the
VRT pin and sink sufficient current from the VRB pin. If these
pins are not driven with devices than can handle the required
current, these reference pins will not be stable, resulting in a
reduction of dynamic performance.
Using a clock source with excessive jitter, using excessively long clock signal trace, or having other signals
coupled to the clock signal trace. This will cause the sampling interval to vary, causing excessive output noise and a
reduction in SNR performance. Simple gates with RC timing
is generally inadequate as a clock source.
Input test signal contains harmonic distortion that interferes with the measurement of dynamic signal to noise
ratio. Harmonic and other interfering signals can be removed
by inserting a filter at the signal input. Suitable filters are
ADC1175-50
Physical Dimensions inches (millimeters) unless otherwise noted
24-Lead Package JM
Order Number ADC1175-50CIJM
Product in the SOIC (EIAJ) package is obsolete. Shown for reference only.
NS Package Number M24D
24-Lead Package TC
Order Number ADC1175-50CIMT
NS Package Number MTC24
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18
ADC1175-50
24-Lead Package LLP
Order Number ADC1175-50CILQX
NS Package Number LQA24A
19
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ADC1175-50 8-Bit, 50 MSPS, 125 mW A/D Converter
Notes
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