General Description
The MAX5888 is an advanced, 16-bit, 500Msps digital-
to-analog converter (DAC) designed to meet the
demanding performance requirements of signal synthe-
sis applications found in wireless base stations and
other communications applications. Operating from a
single 3.3V supply, this DAC offers exceptional dyna-
mic performance such as 76dBc spurious-free dynamic
range (SFDR) at fOUT = 40MHz. The DAC supports
update rates of 500Msps and a power dissipation of
only 250mW.
The MAX5888 utilizes a current-steering architecture,
which supports a full-scale output current range of 2mA
to 20mA, and allows a differential output voltage swing
between 0.1VP-P and 1VP-P.
The MAX5888 features an integrated 1.2V bandgap ref-
erence and control amplifier to ensure high accuracy
and low noise performance. Additionally, a separate
reference input pin enables the user to apply an exter-
nal reference source for optimum flexibility and to
improve gain accuracy.
The digital and clock inputs of the MAX5888 are
designed for differential low-voltage differential signal
(LVDS)-compatible voltage levels. The MAX5888 is
available in a 68-lead QFN package with an exposed
paddle (EP) and is specified for the extended industrial
temperature range (-40°C to +85°C).
Refer to the MAX5887 and MAX5886 data sheets for
pin-compatible 14- and 12-bit versions of the MAX5888.
Applications
Base Stations: Single-/Multicarrier UMTS,
CDMA, GSM
Communications: LMDS, MMDS, Point-to-Point
Microwave
Digital Signal Synthesis
Automated Test Equipment (ATE)
Instrumentation
Features
♦500Msps Output Update Rate
♦Single 3.3V Supply Operation
♦Excellent SFDR and IMD Performance
SFDR = 76dBc at fOUT = 40MHz (to Nyquist)
IMD = -85dBc at fOUT = 10MHz
ACLR = 73dB at fOUT = 61MHz
♦2mA to 20mA Full-Scale Output Current
♦Differential, LVDS-Compatible Digital and Clock
Inputs
♦On-Chip 1.2V Bandgap Reference
♦Low 130mW Power Dissipation
♦68-Lead QFN-EP Package
MAX5888
3.3V, 16-Bit, 500Msps High Dynamic
Performance DAC with Differential LVDS Inputs
________________________________________________________________ Maxim Integrated Products 1
Ordering Information
19-2726; Rev 3; 12/03
For pricing, delivery, and ordering information, please contact Maxim/Dallas Direct! at
1-888-629-4642, or visit Maxim’s website at www.maxim-ic.com.
PART TEMP RANGE PIN-
PACKAGE
MAX5888AEGK -40°C to +85°C 68 QFN-EP*
MAX5888EGK -40°C to +85°C 68 QFN-EP*
5859606162 5455565763
38
39
40
41
42
43
44
45
46
47
VCLK
AGND
B6P
QFN
TOP VIEW
DGND
DVDD
DGND
B7N
B7P
B8N
B8P
B9N
B9P
5253
B10N
B10P
AVDD
FSADJ
REFIO
N.C.
DACREF
AGND
AVDD
IOUTP
IOUTN
AVDD
AGND
AGND
AVDD
AVDD
B13N
B13P
B14N
B14P
B15N
B15P
DGND
DVDD
SEL0
N.C.
35
36
37 N.C.
N.C.
N.C.
DVDD
DGND
B0N
B0P
B1N
VCLK
CLKGND
CLKN
CLKP
CLKGND
B1P
B2N
B2P
B3N
48 B12P
B3P
64
B6N
656667
B4P
B5N
B5P
68
B4N
2322212019 2726252418 2928 323130
AGND
N.C.
3433
49
50 B11P
B12N
51 B11N
11
10
9
8
7
6
5
4
3
2
16
15
14
13
12
1
PD 17
MAX5888
EP
Pin Configuration
*EP = Exposed paddle.
MAX5888
3.3V, 16-Bit, 500Msps High Dynamic
Performance DAC with Differential LVDS Inputs
2 _______________________________________________________________________________________
ABSOLUTE MAXIMUM RATINGS
ELECTRICAL CHARACTERISTICS
(AVDD = DVDD = VCLK = 3.3V, AGND = DGND = CLKGND = 0, external reference, VREFIO = 1.25V, differential transformer-coupled
analog output, 50Ωdouble terminated (Figure 7), IOUT = 20mA, TA= TMIN to TMAX, unless otherwise noted. ≥+25°C guaranteed by
production test, <+25°C guaranteed by design and characterization. Typical values are at TA= +25°C.)
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional
operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to
absolute maximum rating conditions for extended periods may affect device reliability.
AVDD, DVDD, VCLK to AGND................................-0.3V to +3.9V
AVDD, DVDD, VCLK to DGND ...............................-0.3V to +3.9V
AVDD, DVDD, VCLK to CLKGND ...........................-0.3V to +3.9V
AGND, CLKGND to DGND....................................-0.3V to +0.3V
DACREF, REFIO, FSADJ to AGND.............-0.3V to AVDD + 0.3V
IOUTP, IOUTN to AGND................................-1V to AVDD + 0.3V
CLKP, CLKN to CLKGND...........................-0.3V to VCLK + 0.3V
B0P/B0N–B15P/B15N, SEL0,
PD to DGND...........................................-0.3V to DVDD + 0.3V
Continuous Power Dissipation (TA= +70°C)
68-Lead QFN-EP (derate 41.7mW/°C above +70°C) ...3333mW
Thermal Resistance (θJA) ..............................................+24°C/W
Operating Temperature Range ..........................-40°C to +85°C
Junction Temperature .....................................................+150°C
Storage Temperature Range ............................-60°C to +150°C
Lead Temperature (soldering, 10s) ................................+300°C
PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS
STATIC PERFORMANCE
Resolution 16 Bits
MAX5888A___, measured differentially,
TA ≥ +25°C-0.008 ±0.004 +0.008
Integral Nonlinearity INL
MAX5888___, measured differentially,
TA ≥ +25°C±0.006
% FS
MAX5888A___, measured differentially,
TA ≥ +25°C-0.006 ±0.002 +0.006
Differential
Nonlinearity DNL
MAX5888___, measured differentially,
TA ≥ +25°C±0.003
% FS
Offset Error OS -0.025 ±0.003 +0.025 %FS
Offset Drift ±50 ppm/°C
Full-Scale Gain Error GEFS External reference, TA ≥ +25°C -3.1 +1.1 %FS
Internal reference ±100
Gain Drift External reference ±50 ppm/°C
Full-Scale Output Current IOUT (Note 1) 2 20 mA
Min Output Voltage Single ended -0.5 V
Max Output Voltage Single ended 1.1 V
Output Resistance ROUT 1MΩ
Output Capacitance COUT 5pF
DYNAMIC PERFORMANCE
Output Update Rate fCLK 1 500 Msps
fCLK = 300MHz fOUT = 16MHz, -12dB FS -165
Noise Spectral Density fCLK = 500MHz fOUT = 16MHz, -12dB FS -164
dB FS/
Hz
fOUT = 1MHz, 0dB FS 88
fOUT = 1MHz, -6dB FS 89
Spurious-Free Dynamic Range to
Nyquist SFDR fCLK = 100MHz
fOUT = 1MHz, -12dB FS 85
dBc
MAX5888
3.3V, 16-Bit, 500Msps High Dynamic
Performance DAC with Differential LVDS Inputs
_______________________________________________________________________________________ 3
ELECTRICAL CHARACTERISTICS (continued)
(AVDD = DVDD = VCLK = 3.3V, AGND = DGND = CLKGND = 0, external reference, VREFIO = 1.25V, differential transformer-coupled
analog output, 50Ωdouble terminated (Figure 7), IOUT = 20mA, TA= TMIN to TMAX, unless otherwise noted. ≥+25°C guaranteed by
production test, <+25°C guaranteed by design and characterization. Typical values are at TA= +25°C.)
PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS
fOUT = 10MHz, -12dB FS 82
fCLK = 100MHz fOUT = 30MHz, -12dB FS 79
fOUT = 10MHz, -12dB FS 73
fOUT = 16MHz, -12dB FS,
TA ≥ +25°C69 77
fOUT = 50MHz, -12dB FS 72
fCLK = 200MHz
fOUT = 80MHz, -12dB FS 66
fOUT = 10MHz, -12dB FS 67
fOUT = 30MHz, -12dB FS 65
fOUT = 50MHz, -12dB FS 65
Spurious-Free Dynamic Range to
Nyquist SFDR
fCLK = 500MHz
fOUT = 80MHz, -12dB FS 63
dBc
Spurious-Free Dynamic Range,
25MHz Bandwidth SFDR fCLK = 150MHz fOUT = 20MHz, -12dB FS 82 dBc
fCLK = 100MHz fOUT1 = 9MHz, -6dB FS,
fOUT2 = 10MHz, -6dB FS -85
2-Tone IMD TTIMD
fCLK = 300MHz fOU T 1 = 49M H z, - 12d B FS ,
fOU T 2 = 50M H z, - 12d B FS -83
dBc
4-Tone IMD, 1MHz Frequency
Spacing, GSM Model FTIMD fCLK = 300MHz fOUT = 32MHz, -12dB FS -78 dBc
Adjacent Channel Leakage
Power Ratio, 4.1MHz Bandwidth,
WCDMA Model
ACLR fCLK =
184.32MHz fOUT = 61.44MHz 73 dB
Output Bandwidth BW-1dB (Note 2) 450 MHz
REFERENCE
Internal Reference Voltage Range VREFIO 1.13 1.22 1.3 V
Reference Voltage Drift TCOREF ±50 ppm/°C
Reference Input Compliance
Range VREFIOCR 0.125 1.250 V
Reference Input Resistance RREFIO 10 kΩ
ANALOG OUTPUT TIMING
Output Fall Time tFALL 90% to 10% (Note 3) 375 ps
Output Rise Time tRISE 10% to 90% (Note 3) 375 ps
Output Voltage Settling Time tSETTLE Output settles to 0.025% FS (Note 3) 11 ns
Output Propagation Delay tPD (Note 3) 1.8 ns
Glitch Energy 1 pV-s
IOUT = 2mA 30
Output Noise NOUT IOUT = 20mA 30 pA/√Hz
MAX5888
3.3V, 16-Bit, 500Msps High Dynamic
Performance DAC with Differential LVDS Inputs
4 _______________________________________________________________________________________
ELECTRICAL CHARACTERISTICS (continued)
(AVDD = DVDD = VCLK = 3.3V, AGND = DGND = CLKGND = 0, external reference, VREFIO = 1.25V, differential transformer-coupled
analog output, 50Ωdouble terminated (Figure 7), IOUT = 20mA, TA= TMIN to TMAX, unless otherwise noted. ≥+25°C guaranteed by
production test, <+25°C guaranteed by design and characterization. Typical values are at TA= +25°C.)
PARAMETER
SYMBOL
CONDITIONS
MIN TYP MAX
UNITS
TIMING CHARACTERISTICS
Data to Clock Setup Time tSETUP
Referenced to rising edge of clock (Note 4) -0.8
ns
Data to Clock Hold Time tHOLD
Referenced to rising edge of clock (Note 4)
1.8 ns
Data Latency 3.5 Clock
cycles
Minimum Clock Pulse Width High
tCH CLKP, CLKN 0.9 ns
Minimum Clock Pulse Width Low
tCL CLKP, CLKN 0.9 ns
LVDS LOGIC INPUTS (B0N–B15N, B0P–B15P)
Differential Input Logic High VIH
100
mV
Differential Input Logic Low VIL
-100
mV
Common-Mode Voltage Range VCOM
1.125 1.375
V
Differential Input Resistance RIN 85
100
125 Ω
Input Capacitance CIN 5pF
CMOS LOGIC INPUTS (PD, SEL0)
Input Logic High VIH 0.7 ✕
DVDD
V
Input Logic Low VIL 0.3 ✕
DVDD
V
Input Leakage Current IIN -15 +15 µA
Input Capacitance CIN 5pF
CLOCK INPUTS (CLKP, CLKN)
Sine wave
≥1.5
Differential Input Voltage Swing VCLK Square wave
≥0.5
VP-P
Differential Input Slew Rate SRCLK (Note 5)
>100
V/µs
Common-Mode Voltage Range VCOM 1.5
±20%
V
Input Resistance RCLK 5kΩ
Input Capacitance CCLK 5pF
POWER SUPPLIES
Analog Supply Voltage Range AVDD
3.135
3.3
3.465
V
Digital Supply Voltage Range DVDD
3.135
3.3
3.465
V
Clock Supply Voltage Range VCLK
3.135
3.3
3.465
V
fCLK = 100Msps, fOUT = 1MHz 27
Analog Supply Current IAVDD Power-down 0.3 mA
fCLK = 100Msps, fOUT = 1MHz 7 mA
Digital Supply Current IDVDD Power-down 10 µA
fCLK = 100Msps, fOUT = 1MHz 5.6 mA
Clock Supply Current IVCLK Power-down 10 µA
MAX5888
3.3V, 16-Bit, 500Msps High Dynamic
Performance DAC with Differential LVDS Inputs
_______________________________________________________________________________________ 5
Note 1: Nominal full-scale current IOUT = 32 ✕IREF.
Note 2: This parameter does not include update-rate depending effects of sin(x)/x filtering inherent in the MAX5888.
Note 3: Parameter measured single ended into a 50Ωtermination resistor.
Note 4: Parameter guaranteed by design.
Note 5: A differential clock input slew rate of >100V/ms is required to achieve the specified dynamic performance.
Note 6: Parameter defined as the change in midscale output caused by a ±5% variation in the nominal supply voltage.
PARAMETER
SYMBOL
CONDITIONS
MIN TYP MAX
UNITS
fCLK = 100Msps, fOUT = 1MHz
130
Power Dissipation PDISS Power-down 1 mW
Power-Supply Rejection Ratio PSRR
AVDD = VCLK = DVDD = 3.3V ±5% (Note 6)
-1 +1
%FS/V
ELECTRICAL CHARACTERISTICS (continued)
(AVDD = DVDD = VCLK = 3.3V, AGND = DGND = CLKGND = 0, external reference, VREFIO = 1.25V, differential transformer-coupled
analog output, 50Ωdouble terminated (Figure 7), IOUT = 20mA, TA= TMIN to TMAX, unless otherwise noted. ≥+25°C guaranteed by
production test, <+25°C guaranteed by design and characterization. Typical values are at TA= +25°C.)
Typical Operating Characteristics
(AVDD = DVDD = VCLK = 3.3V, external reference, VREFIO = 1.25V, RL= 50Ω, IOUT = 20mA, TA= +25°C, unless otherwise noted.)
0
30
20
10
40
50
60
70
80
90
100
02010 30 40 50
SPURIOUS-FREE DYNAMIC RANGE
vs. OUTPUT FREQUENCY (fCLK = 100MHz)
MAX5888 toc01
fOUT (MHz)
SFDR (dBc)
-12dB FS
0dB FS
-6dB FS
0
30
20
10
40
50
60
70
80
90
100
040
20 30 50 70 90
10 60 80 100
SPURIOUS-FREE DYNAMIC RANGE
vs. OUTPUT FREQUENCY (fCLK = 200MHz)
MAX5888 toc02
fOUT (MHz)
SFDR (dBc)
-6dB FS
-12dB FS 0dB FS
0
30
20
10
40
50
60
70
80
90
100
010050 150 200 250
SPURIOUS-FREE DYNAMIC RANGE
vs. OUTPUT FREQUENCY (fCLK = 500MHz)
MAX5888 toc03
fOUT (MHz)
SFDR (dBc)
-6dB FS
0dB FS
-12dB FS
-100
-70
-80
-90
-60
-50
-40
-30
-20
-10
0
798101112
2-TONE INTERMODULATION DISTORTION
(fCLK = 100MHz)
MAX5888 toc04
fOUT (MHz)
2-TONE IMD (dBm)
2 x fT1 - fT2 2 x fT2 - fT1
fT2 fT1
AOUT = -6dB FS
BW = 5MHz
fT1 = 9.0252MHz
fT2 = 10.0417MHz
-40
-60
-50
-80
-70
-90
-100
0
2-TONE IMD vs. OUTPUT FREQUENCY
(1MHz CARRIER SPACING, fCLK = 300MHz)
MAX5888 toc05
fOUT (MHz)
TWO-TONE IMD (dBc)
5025 75 100
-6dB FS
-12dB FS
-100
-70
-80
-90
-60
-50
-40
-30
-20
-10
0
77 7978 80 81 82
2-TONE INTERMODULATION DISTORTION
(fCLK = 450MHz)
MAX5888 toc06
fOUT (MHz)
2-TONE IMD (dBm)
2 x fT1 - fT2 2 x fT2 - fT1
fT2 fT1
AOUT = -6dB FS
BW = 5MHz
fT1 = 79.2114MHz
fT2 = 80.0903MHz
MAX5888
3.3V, 16-Bit, 500Msps High Dynamic
Performance DAC with Differential LVDS Inputs
6 _______________________________________________________________________________________
Typical Operating Characteristics (continued)
(AVDD = DVDD = VCLK = 3.3V, external reference, VREFIO = 1.25V, RL= 50Ω, IOUT = 20mA, TA= +25°C, unless otherwise noted.)
50
58
66
74
82
90
SFDR vs. TEMPERATURE
(fCLK = 300MHz, AOUT = -6dB FS, IOUT = 20mA)
MAX5888toc08
TEMPERATURE (°C)
SFDR (dBc)
-40 10-15 6035 85
fOUT = 80MHz
fOUT = 120MHz
fOUT = 10MHz
fOUT = 40MHz
0
20
40
60
80
100
SFDR vs. OUTPUT FREQUENCY
(fCLK = 200MHz, AOUT = -6dB FS)
MAX5888toc07
fOUT (MHz)
SFDR (dBc)
04020
10 30 50 70 90
8060 100
IOUT = 20mA
IOUT = 5mA IOUT = 10mA
-3.0
-1.5
0
1.5
3.0
DIFFERENTIAL NONLINEARTIY
vs. DIGITAL INPUT CODE
MAX5888toc10
DIGITAL INPUT CODE
DNL (LSB)
0 300002000010000 5000040000 7000060000
-4.5
-3.0
-1.5
0
1.5
3.0
4.5
INTEGRAL NONLINEARITY
vs. DIGITAL INPUT CODE
MAX5888toc9
DIGITAL INPUT CODE
INL (LSB)
0 300002000010000 5000040000 7000060000
-100
-70
-80
-90
-60
-50
-40
-30
-20
-10
0
26 3028 3432 36 38
8-TONE MULTITONE POWER RATIO PLOT
(fCLK = 300MHz, fCENTER = 31.9702MHz)
MAX5888 toc11
fOUT (MHz)
8-TONE MTPR (dBm)
fT2 f
T6
fT3 f
T7
fT4 f
T8
fT1 f
T5
AOUT = -18dB FS
BW = 12MHz
fT1 = 28.0151MHz
fT2 = 29.0405MHz
fT3 = 30.0659MHz
fT4 = 31.0181MHz
fT5 = 33.06881MHz
fT6 = 34.0209MHz
fT7 = 35.0464MHz
fT8 = 36.0718MHz
80
120
160
200
240
280
POWER DISSIPATION vs. CLOCK FREQUENCY
(fOUT = 10MHz, AOUT = 0dB FS, IOUT = 20mA)
MAX5888toc12
fCLK (MHz)
POWER DISSIPATION (mW)
100 300200 400 500
116
120
124
128
132
136
POWER DISSIPATION vs. SUPPLY VOLTAGE
(fCLK = 100MHz, fOUT = 10MHz, IFS = 20mA)
MAX5888toc13
SUPPLY VOLTAGE (V)
POWER DISSIPATION (mW)
3.135 3.3003.2453.190 3.355 3.410 3.465
EXTERNAL REFERENCE
INTERNAL REFERENCE
MAX5888
3.3V, 16-Bit, 500Msps High Dynamic
Performance DAC with Differential LVDS Inputs
_______________________________________________________________________________________ 7
Pin Description
PIN NAME FUNCTION
1 B3P Data Bit 3
2 B3N Complementary Data Bit 3
3 B2P Data Bit 2
4 B2N Complementary Data Bit 2
5 B1P Data Bit 1
6 B1N Complementary Data Bit 1
7 B0P Data Bit 0 (LSB)
8 B0N Complementary Data Bit 0 (LSB)
9, 41, 60, 62 DGND Digital Ground
10, 40, 61 DVDD Digital Supply Voltage. Accepts a supply voltage range of 3.135V to 3.465V. Bypass each pin with a
0.1µF capacitor to the nearest DGND.
11, 16 VCLK Clock Supply Voltage. Accepts a supply voltage range of 3.135V to 3.465V. Bypass each pin with a
0.1µF capacitor to the nearest CLKGND.
12, 15 CLKGND Clock Ground
13 CLKP Converter Clock Input. Positive input terminal for the differential converter clock.
14 CLKN Complementary Converter Clock Input. Negative input terminal for the differential converter clock.
17 PD Power-Down Input. PD pulled high enables the DAC’s power-down mode. PD pulled low allows for
normal operation of the DAC. This pin features an internal pulldown resistor.
18, 24, 29,
30, 32 AVDD Analog Supply Voltage. Accepts a supply voltage range of 3.135V to 3.465V. Bypass each pin with a
0.1µF capacitor to the nearest AGND.
19, 25, 28,
31, 33, EP AGND Analog Ground. Exposed paddle (EP) must be connected to AGND.
20 REFIO Reference I/O. Output of the internal 1.2V precision bandgap reference. Bypass with a 1µF capacitor
to AGND. Can be driven with an external reference source.
21 FSADJ Full-Scale Adjust Input. This input sets the full-scale output current of the DAC. For 20mA full-scale
output current, connect a 2kΩ resistor between FSADJ and DACREF.
22 DACREF Return Path for the Current Set Resistor. For 20mA full-scale output current, connect a 2kΩ resistor
between FSADJ and DACREF.
23, 34–38 N.C. Not Connected. Do not connect to these pins. Do not tie these pins together.
26 IOUTN Complementary DAC Output. Negative terminal for differential current output. The full-scale output
current range can be set from 2mA to 20mA.
27 IOUTP DAC Output. Positive terminal for differential current output. The full-scale output current range can
be set from 2mA to 20mA.
39 SEL0
Mode Select Input SEL0. Set high to activate the segment shuffling function. Since this pin features an
internal pulldown resistor, it can be left open or pulled low to disable the segment-shuffling function.
See Segment Shuffling in the Detailed Description section for more information.
42 B15P Data Bit 15 (MSB)
43 B15N Complementary Data Bit 15 (MSB)
44 B14P Data Bit 14
MAX5888
3.3V, 16-Bit, 500Msps High Dynamic
Performance DAC with Differential LVDS Inputs
8 _______________________________________________________________________________________
Detailed Description
Architecture
The MAX5888 is a high-performance, 16-bit, current-
steering DAC (Figure 1) capable of operating with clock
speeds up to 500MHz. The converter consists of sepa-
rate input and DAC registers, followed by a current-
steering circuit. This circuit is capable of generating
differential full-scale currents in the range of 2mA to
20mA. An internal current-switching network in combi-
nation with external 50Ωtermination resistors convert
the differential output currents into a differential output
voltage with a peak-to-peak output voltage range of
0.1V to 1V. An integrated 1.2V bandgap reference, con-
trol amplifier, and user-selectable external resistor
determine the data converter’s full-scale output range.
Reference Architecture and Operation
The MAX5888 supports operation with the on-chip 1.2V
bandgap reference or an external reference voltage
source. REFIO serves as the input for an external, low-
impedance reference source, and as the output if the
DAC is operating with the internal reference. For stable
operation with the internal reference, REFIO should be
decoupled to AGND with a 0.1µF capacitor. Due to its
limited output drive capability REFIO must be buffered
with an external amplifier, if heavier loading is required.
The MAX5888’s reference circuit (Figure 2) employs a
control amplifier, designed to regulate the full-scale
current IOUT for the differential current outputs of the
DAC. Configured as a voltage-to-current amplifier, the
output current can be calculated as follows:
IOUT = 32 ✕IREFIO - 1LSB
IOUT = 32 ✕IREFIO - (IOUT / 216)
where IREFIO is the reference output current (IREFIO =
VREFIO/RSET) and IOUT is the full-scale output current of
the DAC. Located between FSADJ and DACREF, RSET
is the reference resistor, which determines the amplifi-
er’s output current for the DAC. See Table 1 for a matrix
of different IOUT and RSET selections.
PIN NAME FUNCTION
45 B14N Complementary Data Bit 14
46 B13P Data Bit 13
47 B13N Complementary Data Bit 13
48 B12P Data Bit 12
49 B12N Complementary Data Bit 12
50 B11P Data Bit 11
51 B11N Complementary Data Bit 11
52 B10P Data Bit 10
53 B10N Complementary Data Bit 10
54 B9P Data Bit 9
55 B9N Complementary Data Bit 9
56 B8P Data Bit 8
57 B8N Complementary Data Bit 8
58 B7P Data Bit 7
59 B7N Complementary Data Bit 7
63 B6P Data Bit 6
64 B6N Complementary Data Bit 6
65 B5P Data Bit 5
66 B5N Complementary Data Bit 5
67 B4P Data Bit 4
68 B4N Complementary Data Bit 4
Pin Description (continued)
MAX5888
3.3V, 16-Bit, 500Msps High Dynamic
Performance DAC with Differential LVDS Inputs
_______________________________________________________________________________________ 9
Analog Outputs (IOUTP, IOUTN)
The MAX5888 outputs two complementary currents
(IOUTP, IOUTN) that can be operated in a single-
ended or differential configuration. A load resistor can
convert these two output currents into complementary
single-ended output voltages. The differential voltage
existing between IOUTP and IOUTN can also be con-
verted to a single-ended voltage using a transformer or
a differential amplifier configuration. If no transformer is
used, the output should have a 50Ωtermination to the
analog ground and a 50Ωresistor between the outputs.
Although not recommended, because of additional
noise pickup from the ground plane, for single-ended
1.2V
REFERENCE
CURRENT-STEERING
DAC
FUNCTION
SELECTION
BLOCK
AGND
SEL0DGND
DVDD
REFIO
REFADJ
CLKN
CLKP
PD
AVDD
IOUTP
IOUTN
SEGMENT SHUFFLING/LATCH
DECODER
LVDS RECEIVER INPUT/LATCH
16
DIFFERENTIAL DIGITAL INPUT B0 THROUGH B15
MAX5888
Figure 1. Simplified MAX5888 Block Diagram
RSET (kΩ)
FULL-SCALE CURRENT
IOUT (mA)
REFERENCE CURRENT
IREF (µA) CALCULATED 1% EIA STD
OUTPUT VOLTAGE
VIOUTP/N* (mVP-P)
2 62.5 19.2 19.1 100
5 156.25 7.68 7.5 250
10 312.5 3.84 3.83 500
15 468.75 2.56 2.55 750
20 625 1.92 1.91 1000
Table 1. IOUT and RSET Selection Matrix Based on a Typical 1.200V Reference Voltage
*Terminated into a 50Ωload.
MAX5888
3.3V, 16-Bit, 500Msps High Dynamic
Performance DAC with Differential LVDS Inputs
10 ______________________________________________________________________________________
operation IOUTP should be selected as the output, with
IOUTN connected to AGND. Note that a single-ended
output configuration has a higher 2nd-order harmonic
distortion at high output frequencies than a differential
output configuration.
Figure 3 displays a simplified diagram of the internal
output structure of the MAX5888.
Clock Inputs (CLKP, CLKN)
The MAX5888 features a flexible differential clock input
(CLKP, CLKN) operating from separate supplies
(VCLK, CLKGND) to achieve the lowest possible jitter
performance. The two clock inputs can be driven from
a single-ended or a differential clock source. For sin-
gle-ended operation, CLKP should be driven by a logic
source, while CLKN should be bypassed to AGND with
a 0.1µF capacitor.
The CLKP and CLKN pins are internally biased to 1.5V.
This allows the user to AC-couple clock sources directly
to the device without external resistors to define the DC
level. The input resistance of CLKP and CLKN is >5kΩ.
See Figure 4 for a convenient and quick way to apply a
differential signal created from a single-ended source
(e.g., HP 8662A signal generator) and a wideband
transformer. These inputs can also be driven from an
LVDS-compatible clock source; however, it is recom-
mended to use sinewave or AC-coupled ECL drive for
best performance.
Data Timing Relationship
Figure 5 shows the timing relationship between differ-
ential, digital LVDS data, clock, and output signals. The
MAX5888 features a 1.4ns hold, a -1ns setup, and a
1.8ns propagation delay time. There is a 3.5 clock-
cycle latency between CLKP/CLKN transitioning
high/low and IOUTP/IOUTN.
LVDS-Compatible Digital Inputs
(B0P–B15P, B0N–B15N)
The MAX5888 features LVDS receivers on the bus input
interface. These LVDS inputs (B0P/N through B15P/N)
allow for a low-differential voltage swing with low con-
stant power consumption across a large range of
0.1µF
1.2V
REFERENCE
10kΩ
IREF
RSET
DACREF
FSADJ
REFIO
IREF = VREFIO/RSET
CURRENT-STEERING
DAC
AVDD
IOUTP
IOUTN
Figure 2. Reference Architecture, Internal Reference
Configuration
IOUT
IOUT
IOUTN IOUTP
CURRENT
SOURCES
CURRENT
SWITCHES
AVDD
Figure 3. Simplified Analog Output Structure
SINGLE-ENDED
CLOCK SOURCE
(e.g., HP 8662A)
1:1
WIDEBAND RF TRANSFORMER
PERFORMS SINGLE-ENDED TO
DIFFERENTIAL CONVERSION.
TO
DAC
CLKP
0.1µF
0.1µFCLKN
CLKGND
25Ω
25Ω
Figure 4. Differential Clock Signal Generation
MAX5888
3.3V, 16-Bit, 500Msps High Dynamic
Performance DAC with Differential LVDS Inputs
______________________________________________________________________________________ 11
frequencies. Their differential characteristic supports
the transmission of high-speed data patterns without
the negative effects of electromagnetic interference
(EMI). All MAX5888 LVDS inputs feature on-chip termi-
nation with differential 100Ωresistors. See Figure 6 for
a simplified block diagram of the LVDS inputs.
A common-mode level of 1.25V and an 800mV differen-
tial input swing can be applied to these inputs.
Segment Shuffling (SEL0)
Segment shuffling can improve the SFDR of the
MAX5888. The improvement is most pronounced at
higher output frequencies and amplitudes. Note that an
improvement in SFDR can only be achieved at the cost
of a slight increase in the DAC’s noise floor.
Pin SEL0 controls the segment-shuffling function. If
SEL0 is pulled low, the segment-shuffling function of
the DAC is disabled. SEL0 can also be left open,
because an internal pulldown resistor helps to deacti-
vate the segment-shuffling feature. To activate the
MAX5888 segment-shuffling function, SEL0 must be
pulled high.
Power-Down Operation (PD)
The MAX5888 also features an active-high power-down
mode, which allows the user to cut the DAC’s digital
current consumption to less than 6µA and the analog
current consumption to less than 0.3mA. A single pin
(PD) is used to control the power-down mode (PD = 1)
or reactivate the DAC (PD = 0) after power-down.
Enabling the power-down mode of the MAX5888 allows
the overall power consumption to be reduced to less
than 1mW. The MAX5888 requires 10ms to wake up
from power-down and enter a fully operational state.
Applications Information
Differential Coupling Using a
Wideband RF Transformer
The differential voltage existing between IOUTP and
IOUTN can also be converted to a single-ended volt-
age using a transformer (Figure 7) or a differential
amplifier configuration. Using a differential transformer
coupled output, in which the output power is limited to
0dBm, can optimize the dynamic performance.
However, make sure to pay close attention to the trans-
former core saturation characteristics when selecting a
transformer for the MAX5888. Transformer core satura-
tion can introduce strong 2nd-harmonic distortion,
especially at low output frequencies and high signal
B0 TO B15
CLKN
CLKP
IOUT
N
DIGITAL DATA IS LATCHED ON
THE RISING EDGE OF CLKP
OUTPUT DATA IS UPDATED ON
THE FALLING EDGE OF CLKP
N + 1 N + 2
N - 5 N - 3 N - 1N - 2N - 4
tSETUP tHOLD
tPD
tCH tCL
N - 1
Figure 5. Detailed Timing Relationship
100Ω
B0P–B15P
B0N–B15N
DQ
DQ
CLOCK
TO DECODE
LOGIC
Figure 6. Simplified LVDS-Compatible Input Structure
MAX5888
3.3V, 16-Bit, 500Msps High Dynamic
Performance DAC with Differential LVDS Inputs
12 ______________________________________________________________________________________
amplitudes. It is also recommended to center tap the
transformer to ground. If no transformer is used, each
DAC output should be terminated to ground with a 50Ω
resistor. Additionally, a 100Ωresistor should be placed
between the outputs (Figure 8).
If a single-ended unipolar output is desirable, IOUTP
should be selected as the output, with IOUTN ground-
ed. However, driving the MAX5888 single ended is not
recommended since additional noise is added (from
the ground plane) in such configurations.
The distortion performance of the DAC depends on the
load impedance. The MAX5888 is optimized for a 50Ω
double termination. It can be used with a transformer
output as shown in Figure 7 or just one 50Ωresistor
from each output to ground and one 50Ωresistor
between the outputs. This produces a full-scale output
power of up to 0dBm depending on the output current
setting. Higher termination impedance can be used at
the cost of degraded distortion performance and
increased output noise voltage.
Adjacent Channel Leakage Power Ratio
(ACLR) Testing for CDMA- and
WCDMA-Based Base Station
Transceiver Systems (BTS)
The transmitter sections of BTS applications serving
CDMA and WCDMA architectures must generate carri-
ers with minimal coupling of carrier energy into the adja-
cent channels. Similar to the GSM/EDGE model (see the
Multitone Testing for GSM/EDGE Applications section in
the Applications section), a transmit mask (Tx mask)
exists for this application. The spread-spectrum modula-
tion function applied to the carrier frequency generates a
spectral response, which is uniform over a given band-
width (up to 4MHz) for a WCDMA-modulated carrier.
A dominant specification is ACLR, a parameter which
reflects the ratio of the power in the desired carrier
band to the power in an adjacent carrier band. The
specification covers the first two adjacent bands, and is
measured on both sides of the desired carrier.
According to the transmit mask for CDMA and WCDMA
architectures, the power ratio of the integrated carrier
channel energy to the integrated adjacent channel
energy must be >45dB for the first adjacent carrier slot
(ACLR 1) and >50dB for the second adjacent carrier
slot (ACLR 2). This specification applies to the output of
the entire transmitter signal chain. The requirement for
only the DAC block of the transmitter must be tighter,
with a typical margin of >15dB, requiring the DAC’s
ACLR 1 to be better than 60dB. Adjacent channel leak-
age is caused by a single-spread spectrum carrier,
which generates intermodulation (IM) products
between the frequency components located within the
carrier band. The energy at one end of the carrier band
generates IM products with the energy from the oppo-
site end of the carrier band. For single-carrier WCDMA
modulation, these IMD products are spread 3.84MHz
over the adjacent sideband. Four contiguous WCDMA
MAX5888
T2, 1:1
T1, 1:1
VOUT, SINGLE ENDED
WIDEBAND RF TRANSFORMER T2
PERFORMS THE DIFFERENTIAL TO
SINGLE-ENDED CONVERSION.
50Ω
100Ω
50Ω
IOUTP
IOUTN
B0–B15
16
AVDD DVDD VCLK
AGND DGND CLKGND
Figure 7. Differential to Single-Ended Conversion Using a Wideband RF Transformer
MAX5888
50Ω
100Ω
50Ω
IOUTP
IOUTN
B0–B15
16
AVDD DVDD VCLK
AGND DGND CLKGND
OUTP
OUTN
Figure 8. MAX5888 Differential Output Configuration
MAX5888
3.3V, 16-Bit, 500Msps High Dynamic
Performance DAC with Differential LVDS Inputs
______________________________________________________________________________________ 13
carriers spread their IM products over a bandwidth of
20MHz on either side of the 20MHz total carrier band-
width. In this four-carrier scenario, only the energy in
the first adjacent 3.84MHz side band is considered for
ACLR 1. To measure ACLR, drive the converter with a
WCDMA pattern. Make sure that the signal is backed
off by the peak-to-average ratio, such that the DAC is
not clipping the signal. ACLR can then be measured
with the ACLR measurement function built into your
spectrum analyzer.
Figure 9 shows the ACLR performance for a single
WCDMA carrier (fCLK = 184.32MHz, fOUT = 61.44MHz)
applied to the MAX5888 (including measurement sys-
tem limitations*).
Figure 10 illustrates the ACLR test results for the
MAX5888 with a four-carrier WCDMA signal at an out-
put frequency of 61.44MHz and sampling frequency of
184.32MHz. Again, the noise floor of the instrument
restricts the signal’s real dynamic range of the signal,
and the measured ACLR 1 understates the actual by
more than 2.5dB. Considerable care must be taken to
ensure accurate measurement of this parameter.
Multitone Testing for GSM/EDGE
Applications
The transmitter sections of multicarrier base station
transceiver systems for GSM/EDGE usually present
communication DAC manufacturers with the difficult
task of providing devices with higher resolution, while
simultaneously reducing noise and spurious emissions
over a desired bandwidth.
To specify noise and spurious emissions from base sta-
tions, a GSM/EDGE Tx mask is used to identify the DAC
requirements for these parameters. This mask shows
that the allowable levels for noise and spurious emis-
sions are dependent on the offset frequency from the
transmitted carrier frequency. The GSM/EDGE mask
and its specifications are based on a single active car-
rier with any other carriers in the transmitter being dis-
abled. Specifications displayed in Figure 11 support
per-carrier output power levels of 20W or greater.
Lower output power levels yield less stringent emission
requirements. For GSM/EDGE applications, the DAC
demands spurious emission levels of less than -80dBc
for offset frequencies ≥6MHz. Spurious products from
the DAC can combine with both random noise and spu-
rious products from other circuit elements. The spuri-
ous products from the DAC should therefore be backed
off by 6dB more to allow for these other sources and
still avoid signal clipping.
*Note that due to their own IM effects and noise limitations, spectrum analyzers introduce ACLR errors, which can falsify the measure-
ment. For a single-carrier ACLR measurement greater than 70dB, these measurement limitations are significant, becoming even more
restricting for multicarrier measurement. Before attempting an ACLR measurement, it is recommended consulting application notes pro-
vided by major spectrum analyzer manufacturers that provide useful tips on how to use their instruments for such tests.
-125
-100
-110
-120
-90
-80
-70
-60
-50
-30
-40
OUTPUT POWER (dBm)
-25
3.5MHz/div
fCENTER = 61.44MHz
fCLK = 184.32Mbps
ACLR = 73dB
Figure 9. ACLR for WCDMA Modulation, Single Carrier
-130
-100
-110
-120
-90
-80
-70
-60
-50
-30
-40
3.5MHz/div
fCENTER = 61.44MHz
fCLK = 184.32Mbps
ACLR = 65dB
OUTPUT POWER (dBm)
Figure 10. ACLR for WCDMA Modulation, Four Carriers
MAX5888
3.3V, 16-Bit, 500Msps High Dynamic
Performance DAC with Differential LVDS Inputs
14 ______________________________________________________________________________________
The number of carriers and their signal levels with
respect to the full scale of the DAC are important as
well. Unlike a full-scale sine wave, the inherent nature of
a multitone signal contains higher peak-to-RMS ratios,
raising the prospect for potential clipping, if the signal
level is not backed off appropriately. If a transmitter
operates with four/eight in-band carriers, each individ-
ual carrier must be operated at less than
-12dB FS/-18dB FS to avoid waveform clipping.
The noise density requirements (Table 2) for a
GSM/EDGE-based system can again be derived from
the system’s Tx mask. With a worst-case noise level of
-80dBc at frequency offsets of ≥6MHz and a measure-
ment bandwidth of 100kHz, the minimum noise density
per hertz is calculated as follows:
SNRMIN = -80dBc - 10 ✕log10(100 ✕103Hz)
SNRMIN = -130dBc/Hz
Since random DAC noise adds to both the spurious tones
and to random noise from other circuit elements, it is rec-
ommended reducing the specification limits by about
10dB to allow for these additional noise contributions
while maintaining compliance with the Tx mask values.
Other key factors in selecting the appropriate DAC for
the Tx path of a multicarrier GSM/EDGE system is the
converter’s ability to offer superior IMD and MTPR perfor-
mance. Multiple carriers in a designated band generate
unwanted intermodulation distortion between the individ-
ual carrier frequencies. A multitone test vector usually
consists of several equally spaced carriers, usually four,
with identical amplitudes. Each of these carriers is rep-
resentative of a channel within the defined bandwidth of
interest. To verify MTPR, one or more tones are
removed such that the intermodulation distortion perfor-
mance of the DAC can be evaluated. Nonlinearities
associated with the DAC create spurious tones, some
of which may fall back into the area of the removed
tone, limiting a channel’s carrier-to-noise ratio. Other
spurious components falling outside the band of inter-
est can also be important, depending on the system’s
spectral mask and filtering requirements. Going back to
the GSM/EDGE Tx mask, the IMD specification for adja-
cent carriers varies somewhat among the different GSM
standards. For the PCS1800 and GSM850 standards,
the DAC must meet an average IMD of -70dBc.
Table 3 summarizes the dynamic performance require-
ments for the entire Tx signal chain in a four-carrier
GSM/EDGE-based system and compares the previous-
ly established converter requirements with a new-gen-
eration high dynamic performance DAC.
The four-tone MTPR plot in Figure 12 demonstrates the
MAX5888’s excellent dynamic performance. The center
frequency (fCENTER = 31.97MHz) has been removed to
allow detection and analysis of intermodulation or spuri-
ous components falling back into this empty spot from
adjacent channels. The four carriers are observed over
a 12MHz bandwidth and are equally spaced at 1MHz.
Each individual output amplitude is backed off to -12dB
FS. Under these conditions, the DAC yields an MTPR
performance of -78dBc.
NUMBER OF
CARRIERS
CARRIER
POWER LEVEL
(dB FS)
DAC NOISE DENSITY
REQUIREMENT
(dB FS/Hz)
2 -6 -146
4 -12 -152
8 -18 -158
Table 2. GSM/EDGE Noise Requirements
for Multicarrier Systems
SPECIFICATION SYSTEM TRANSMITTER
OUTPUT LEVELS
DAC REQUIREMENTS WITH
MARGINS MAX5888 SPECIFICATIONS
SFDR 80dBc 86dBc 82dBc*
SNR -130dBc/Hz -152dB FS/Hz -165dB/Hz
IMD -70dBc -75dBc -78dBc
Carrier Amplitude N/S -12dB FS -12dB FS
Table 3. Summary of Important AC Performance Parameters for Multicarrier GSM/EDGE
Systems
*Measured within a 25MHz window.
MAX5888
3.3V, 16-Bit, 500Msps High Dynamic
Performance DAC with Differential LVDS Inputs
______________________________________________________________________________________ 15
Grounding, Bypassing, and Power-Supply
Considerations
Grounding and power-supply decoupling can strongly
influence the performance of the MAX5888. Unwanted
digital crosstalk may couple through the input, refer-
ence, power supply, and ground connections, affecting
dynamic performance. Proper grounding and power-
supply decoupling guidelines for high-speed, high-fre-
quency applications should be closely followed. This
reduces EMI and internal crosstalk that can significant-
ly affect the dynamic performance of the MAX5888.
Use of a multilayer printed circuit (PC) board with sepa-
rate ground and power-supply planes is recommend-
ed. High-speed signals should run on lines directly
above the ground plane. Since the MAX5888 has sepa-
rate analog and digital ground buses (AGND,
CLKGND, and DGND, respectively), the PC board
should also have separate analog and digital ground
sections with only one point connecting the two planes.
Digital signals should be run above the digital ground
plane and analog/clock signals above the analog/clock
ground plane. Digital signals should be kept as far
away from sensitive analog inputs, reference inputs
sense lines, common-mode input, and clock inputs as
practical. A symmetric design of clock input and ana-
log output lines is recommended to minimize 2nd-order
harmonic distortion components and optimize the
DAC’s dynamic performance. Digital signal paths
should be kept short and run lengths matched to avoid
propagation delay and data skew mismatches.
The MAX5888 supports three separate power-supply
inputs for analog (AVDD), digital (DVDD), and clock
(VCLK) circuitry. Each AVDD, DVDD, and VCLK input
should at least be decoupled with a separate 0.1µF
capacitor as close to the pin as possible and their
opposite ends with the shortest possible connection to
the corresponding ground plane (Figure 13). Try to
minimize the analog and digital load capacitances for
optimized operation. All three power-supply voltages
should also be decoupled at the point they enter the
PC board with tantalum or electrolytic capacitors.
Ferrite beads with additional decoupling capacitors
forming a pi network could also improve performance.
The analog and digital power-supply inputs AVDD,
VCLK, and DVDD of the MAX5888 allow a supply volt-
age range of 3.3V ±5%.
O
-30
-60
-70
-73
-75
-80
-90
0.2 0.4 0.6 1.2 1.8 6.0
IMD REQUIREMENT: < -70dBc
30kHz 100kHz
MEASUREMENT BANDWIDTH
TRANSMITTER EDGE
INBAND OUTBAND
WORST-CASE
NOISE LEVEL
AMPLITUDE (dBc)
FREQUENCY OFFSET FROM CARRIER (MHz)
Figure 11. GSM/EDGE Tx Mask
-100
-70
-80
-90
-60
-50
-40
-30
-20
-10
0
26 3028 3432 36 38
4-TONE MULTITONE POWER RATIO PLOT
(fCLK = 300MHz, fCENTER = 31.9702MHz)
fOUT (MHz)
4-TONE MTPR (dBm)
fT2
fT3
fT4
fT1
AOUT = -12dB FS
BW = 12MHz
fT1 = 30.0659MHz
fT2 = 31.0181MHz
fT3 = 33.0688MHz
fT4 = 34.0209MHz
Figure 12. 4-Tone MTPR Test Results, fCENTER = 31.97MHz,
fCLK = 300MHz
MAX5888
3.3V, 16-Bit, 500Msps High Dynamic
Performance DAC with Differential LVDS Inputs
16 ______________________________________________________________________________________
The MAX5888 is packaged in a 68-lead QFN-EP
package (package code: G6800-4), providing greater
design flexibility, increased thermal efficiency**, and
optimized AC performance of the DAC. The exposed
pad (EP) enables the user to implement grounding
techniques, which are necessary to ensure highest per-
formance operation. The EP must be soldered down
to AGND.
In this package, the data converter die is attached to
an EP lead frame with the back of this frame exposed at
the package bottom surface, facing the PC board side
of the package. This allows a solid attachment of the
package to the PC board with standard infrared (IR)
flow soldering techniques. A specially created land pat-
tern on the PC board, matching the size of the EP (6mm
✕6mm), ensures the proper attachment and grounding
of the DAC. Designing vias*** into the land area and
implementing large ground planes in the PC board
design allow for highest performance operation of the
DAC. An array of at least 4 ✕4 vias (≤0.3mm diameter
per via hole and 1.2mm pitch between via holes) is rec-
ommended for this 68-lead QFN-EP package.
Static Performance Parameter Definitions
Integral Nonlinearity (INL)
Integral nonlinearity is the deviation of the values on an
actual transfer function from either a best straight line fit
(closest approximation to the actual transfer curve) or a
line drawn between the end points of the transfer func-
tion, once offset and gain errors have been nullified. For
a DAC, the deviations are measured at every individual
step.
Differential Nonlinearity (DNL)
Differential nonlinearity is the difference between an
actual step height and the ideal value of 1 LSB. A DNL
error specification of less than 1 LSB guarantees no
missing codes and a monotonic transfer function.
FERRITE BEAD
AVDD
1µF10µF47µFANALOG POWER-
SUPPLY SOURCE
FERRITE BEAD
DVDD
1µF10µF47µFDIGITAL POWER-
SUPPLY SOURCE
FERRITE BEAD
VCLK
1µF10µF47µFCLOCK POWER-
SUPPLY SOURCE
AVDD
AGND
MAX5888
B0–B15
16
0.1µF
DGND
0.1µF
VCLK
CLKGND
0.1µF
OUTP
OUTN
DVDD
BYPASSING—DAC LEVEL BYPASSING—BOARD LEVEL
Figure 13. Recommended Power-Supply Decoupling and Bypassing Circuitry
**Thermal efficiency is not the key factor, since the MAX5888 features low-power operation. The exposed pad is the key element to
ensure a solid ground connection between the DAC and the PC board’s analog ground layer.
***Vias connect the land pattern to internal or external copper planes. It is important to connect as many vias as possible to the analog
ground plane to minimize inductance.
MAX5888
3.3V, 16-Bit, 500Msps High Dynamic
Performance DAC with Differential LVDS Inputs
______________________________________________________________________________________ 17
Offset Error
The offset error is the difference between the ideal and
the actual offset current. For a DAC, the offset point is
the value at the output for the two midscale digital input
codes with respect to the full scale of the DAC. This
error affects all codes by the same amount.
Gain Error
A gain error is the difference between the ideal and the
actual full-scale output voltage on the transfer curve,
after nullifying the offset error. This error alters the slope
of the transfer function and corresponds to the same
percentage error in each step.
Settling Time
The settling time is the amount of time required from the
start of a transition until the DAC output settles its new
output value to within the converter’s specified accuracy.
Glitch Energy
Glitch impulses are caused by asymmetrical switching
times in the DAC architecture, which generates unde-
sired output transients. The amount of energy that
appears at the DAC’s output is measured over time and
usually specified in the pV-s range.
Dynamic Performance Parameter
Definitions
Signal-to-Noise Ratio (SNR)
For a waveform perfectly reconstructed from digital sam-
ples, the theoretical maximum SNR is the ratio of the full-
scale analog output (RMS value) to the RMS quantization
error (residual error). The ideal, theoretical minimum can
be derived from the DAC’s resolution (N bits):
SNRdB = 6.02dB ✕N + 1.76dB
However, noise sources such as thermal noise, refer-
ence noise, clock jitter, etc., affect the ideal reading;
therefore, SNR is computed by taking the ratio of the
RMS signal to the RMS noise, which includes all spec-
tral components minus the fundamental, the first four
harmonics, and the DC offset.
Spurious-Free Dynamic Range (SFDR)
SFDR is the ratio of RMS amplitude of the carrier fre-
quency (maximum signal components) to the RMS
value of their next-largest distortion component. SFDR
is usually measured in dBc and with respect to the car-
rier frequency amplitude or in dB FS with respect to the
DAC’s full-scale range. Depending on its test condition,
SFDR is observed within a predefined window or
to Nyquist.
Two-/Four-Tone Intermodulation
Distortion (IMD)
The two-tone IMD is the ratio expressed in dBc (or dB
FS) of either input tone to the worst 3rd-order (or high-
er) IMD products. Note that 2nd-order IMD products
usually fall at frequencies that can be easily removed
by digital filtering; therefore, they are not as critical as
3rd-order IMDs. The two-tone IMD performance of the
MAX5888 was tested with the two individual input tone
levels set to at least -6dB FS and the four-tone perfor-
mance was tested according to the GSM model at an
output frequency of 32MHz and amplitude of -12dB FS.
Adjacent Channel Leakage
Power Ratio (ACLR)
Commonly used in combination with WCDMA, ACLR
reflects the leakage power ratio in dB between the
measured power within a channel relative to its adja-
cent channel. ACLR provides a quantifiable method of
determining out-of-band spectral energy and its influ-
ence on an adjacent channel when a bandwidth-limited
RF signal passes through a nonlinear device.
Chip Information
TRANSISTOR COUNT: 10,629
PROCESS: CMOS
MAX5888
3.3V, 16-Bit, 500Msps High Dynamic
Performance DAC with Differential LVDS Inputs
Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are
implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.
18 ____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600
© 2003 Maxim Integrated Products Printed USA is a registered trademark of Maxim Integrated Products.
Package Information
(The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information,
go to www.maxim-ic.com/packages.)
Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are
implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.
18 ____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600
© 2003 Maxim Integrated Products Printed USA is a registered trademark of Maxim Integrated Products.
Package Information
(The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information,
go to www.maxim-ic.com/packages.)
68L QFN.EPS
C
1
2
21-0122
PACKAGE OUTLINE, 68L QFN, 10x10x0.9 MM
C
1
2
21-0122
PACKAGE OUTLINE, 68L QFN, 10x10x0.9 MM
*MAX5888 Package Code
*
