MAX5631/MAX5632/ MAX5633 16-Bit DACs with 32-Channel Sample-and-Hold Outputs General Description Ordering Information PART TEMP RANGE* MAX5631UCB+D 0C to +85C 64 TQFP MAX5631UTK+ 0C to +85C 68 TQFN-EP** 0C to +85C 64 TQFP MAX5632UTK+ 0C to +85C 68 TQFN-EP** MAX5633UCB+D 0C to +85C 64 TQFP MAX5633UTK+ 0C to +85C 68 TQFN-EP** +Denotes a lead(Pb)-free/RoHS-compliant package. *For other temperature-range options, contact factory. **EP = Exposed pad. Industrial Process Control Automatic Test Equipment Instrumentation CL OUT21 OUT22 OUT24 OUT23 OUT25 AGND OUT26 63 62 61 60 59 58 OUT27 64 57 56 55 54 53 52 51 50 49 + N.C. 1 N.C. 2 47 CH 48 VDD GS 3 46 VSS VLDAC 4 45 OUT20 RST 5 44 OUT19 CS 6 43 OUT18 DIN 7 42 OUT17 SCLK 8 41 OUT16 VLOGIC 9 MAX5631 MAX5632 MAX5633 IMMED 10 Pin Configurations continued at end of data sheet. OUT28 OUT29 OUT30 TOP VIEW OUT31 Pin Configurations ________________________Applications MEMS Mirror Servo Control PIN-PACKAGE MAX5632UCB+D AGND These devices are controlled through a 20MHz SPI/QSPITM/MICROWIRE (R) -compatible 3-wire serial interface. Immediate Update Mode allows any channel's output to be updated within 20s. Burst Mode allows multiple values to be loaded into memory in a single, high-speed data burst. All channels are updated within 330s after data has been loaded. Each device features an output clamp and output resistors for filtering. The MAX5631 features a 50 output impedance and is capable of driving up to 250pF of output capacitance. The MAX5632 features a 500 output impedance and is capable of driving up to 10nF of output capacitance. The MAX5633 features a 1k output impedance and is capable of driving up to 10nF of output capacitance. The MAX5631/MAX5632/MAX5633 are available in 12mm x 12mm, 64-pin TQFP, and 10mm x 10mm, 68-pin thin QFN packages. CH The MAX5631/MAX5632/MAX5633 feature a -4.5V to +9.2V output voltage range. Other features include a 200V/step resolution, with output linearity error, typically 0.005% of full-scale range (FSR). The 100kHz refresh-rate updates each SHA every 320s, resulting in negligible output droop. Remote ground sensing allows the outputs to be referenced to the local ground of a separate device. Features o Integrated 16-Bit DAC and 32-Channel SHA with SRAM and Sequencer o 32 Voltage Outputs o 0.005% Output Linearity o 200V Output Resolution o Flexible Output Voltage Range o Remote Ground Sensing o Fast Sequential Loading: 1.3s per Register o Burst and Immediate Mode Addressing o No External Components Required for Setting Gain and Offset o Integrated Output Clamp Diodes o Three Output Impedance Options: MAX5631 (50), MAX5632 (500), and MAX5633 (1k) VREF The MAX5631/MAX5632/MAX5633 are 16-bit digital-toanalog converters (DACs) with 32 sample-and-hold (SHA) outputs for applications where a high number of programmable voltages are required. These devices include a clock oscillator and a sequencer that updates the DAC with codes from an internal SRAM. No external components are required to set offset and gain. 40 AGND 39 VDD ECLK 11 38 OUT15 CLKSEL 12 37 OUT14 DGND 13 36 OUT13 VLSHA 14 35 OUT12 AGND 15 34 OUT11 33 CL VSS 16 VSS CH OUT10 OUT9 OUT8 OUT7 OUT6 AGND OUT5 OUT4 OUT3 OUT2 OUT1 CL OUT0 QSPI is a trademark of Motorola, Inc. MICROWIRE is a registered trademark of National Semiconductor, Corp. VDD 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 TQFP For pricing, delivery, and ordering information, please contact Maxim Direct at 1-888-629-4642, or visit Maxim's website at www.maximintegrated.com. 19-2171; Rev 4; 9/12 MAX5631/MAX5632/MAX5633 16-Bit DACs with 32-Channel Sample-and-Hold Outputs ABSOLUTE MAXIMUM RATINGS VDD to AGND.......................................................-0.3V to +12.2V VSS to AGND .........................................................-6.0V to +0.3V VDD to VSS ...........................................................................+15V VLDAC, VLOGIC, VLSHA to AGND or DGND ..............-0.3V to +6V REF to AGND............................................................-0.3V to +6V GS to AGND................................................................VSS to VDD CL and CH to AGND...................................................VSS to VDD Logic Inputs to DGND ..............................................-0.3V to +6V DGND to AGND........................................................-0.3V to +2V Maximum Current Into OUT_ ............................................10mA Maximum Current Into Logic Inputs .................................20mA Continuous Power Dissipation (TA = +70C) 64-Pin TQFP (derate 13.3mW/C above +70C) ............1066mW 68-Pin TQFN-EP (derate 28.6mW/C above +70C) ......2285mW Operating Temperature Range...............................0C to +85C Maximum Junction Temperature .....................................+150C Storage Temperature Range .............................-65C to +150C Lead Temperature (soldering, 10s) .................................+300C Soldering Temperature (reflow) .......................................+260C 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. ELECTRICAL CHARACTERISTICS (VDD = +10V, VSS = -4V, VLOGIC = VLDAC = VLSHA = +5V, VREF = +2.5V, VAGND = VDGND = VGS = 0V, RL 10M, CL = 50pF, CLKSEL = +5V, fECLK = 400kHz, TA = TMIN to TMAX, unless otherwise noted. Typical values are at TA = +25C.) PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS DC CHARACTERISTICS Resolution Output Range N VOUT_ Offset Voltage 16 (Note 1) 15 Code = 4F2C hex 200 50 Gain Error (Note 2) Integral Linearity Error INL VOUT_ = -3.25V to +7.6V Differential Linearity Error DNL VOUT_ = -3.25V to +7.6V. Monotonicity guaranteed to 14 bits Maximum Output Drive Current IOUT Sinking and sourcing DC Output Impedance ROUT Maximum Capacitive Load DC Crosstalk PSRR V mV V/C 1 5 Gain Tempco 2 VDD 2.4 VSS + 0.75 Offset Voltage Tempco Power-Supply Rejection Ratio Bits % ppm/C 0.005 0.015 %FSR 1 4 LSB 2 mA MAX5631 35 50 65 MAX5632 350 500 650 MAX5633 700 1000 1300 MAX5631 250 MAX5632 10 pF MAX5633 10 Internal oscillator enabled (Note 3) -90 dB Internal oscillator enabled -80 dB nF Maxim Integrated MAX5631/MAX5632/MAX5633 16-Bit DACs with 32-Channel Sample-and-Hold Outputs ELECTRICAL CHARACTERISTICS (continued) (VDD = +10V, VSS = -4V, VLOGIC = VLDAC = VLSHA = +5V, VREF = +2.5V, VAGND = VDGND = VGS = 0V, RL 10M, CL = 50pF, CLKSEL = +5V, fECLK = 400kHz, TA = TMIN to TMAX, unless otherwise noted. Typical values are at TA = +25C.) PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS 0.08 % DYNAMIC CHARACTERISTICS Sample-and-Hold Settling (Note 4) SCLK Feedthrough 0.5 nV-s fSEQ Feedthrough 0.5 nV-s Hold-Step Droop Rate VOUT_ = 0V (Note 5), TA = +25C Output Noise 0.25 1 mV 1 40 mV/s VRMS 250 REFERENCE INPUT Input Resistance Reference Input Voltage 7 VREF k 2.5 V GROUND-SENSE INPUT Input Voltage Range VGS Input Bias Current IGS GS Gain -0.5V VGS 0.5V (Note 6) -0.5 0.5 V -60 0 A 1.002 V/V 0.998 1 DIGITAL INTERFACE DC CHARACTERISTICS Input High Voltage VIH Input Low Voltage VIL 2.0 V Input Current 0.8 V 1 A 120 kHz TIMING CHARACTERISTICS (FIGURE 2) Sequencer Clock Frequency fSEQ Internal oscillator External Clock Frequency fECLK (Note 7) SCLK Frequency fSCLK 80 100 480 kHz 20 MHz SCLK Pulse Width High tCH 15 ns SCLK Pulse Width Low tCL 15 ns CS Low to SCLK High Setup Time tCSSO 15 ns CS High to SCLK High Setup Time tCSS1 15 ns SCLK High to CS Low Hold Time tCSH0 10 ns Maxim Integrated 3 MAX5631/MAX5632/MAX5633 16-Bit DACs with 32-Channel Sample-and-Hold Outputs ELECTRICAL CHARACTERISTICS (continued) (VDD = +10V, VSS = -4V, VLOGIC = VLDAC = VLSHA = +5V, VREF = +2.5V, VAGND = VDGND = VGS = 0V, RL 10M, CL = 50pF, CLKSEL = +5V, fECLK = 400kHz, TA = TMIN to TMAX, unless otherwise noted. Typical values are at TA = +25C.) PARAMETER SYMBOL SCLK High to CS High Hold Time CONDITIONS MIN TYP MAX UNITS tCSH1 0 ns DIN to SCLK High Setup Time tDS 15 ns DIN to SCLK High Hold Time tDH 0 ns RST to CS Low (Note 8) 500 s POWER SUPPLIES Positive Supply Voltage VDD (Note 9) 8.55 10 11.6 V Negative Supply Voltage VSS (Note 9) -5.25 -4 -2.75 V 14.5 V 5 5.25 V 32 42 mA mA Supply Difference Logic Supply Voltage VDD - VSS (Note 9) VLOGIC, VLDAC, VLSHA Positive Supply Current IDD Negative Supply Current ISS Logic Supply Current ILOGIC 4.75 32 40 (Note 10) 1 1.5 fSCLK = 20MHz (Note 11) 2 3 mA Note 1: The nominal zero-scale (code = 0) voltage is -4.0535V. The nominal full-scale (code = FFFF hex) voltage is +9.0535V. The output voltage is limited by the Output Range specification, restricting the useable range of DAC codes. The nominal zeroscale voltage may be achieved when VSS < -4.9V, and the nominal full-scale voltage may be achieved when VDD > +11.5V. Note 2: Gain is calculated from measurements for voltages VDD = 10V and VSS = -4V at codes C000 hex and 4F2C hex, for voltages VDD = 11.6V and VSS = -2.9V at codes FFFF hex and 252E hex, for voltages VDD = 9.25V and VSS = -5.25V at codes D4F6 hex and 0 hex, and for voltages VDD = 8.55V and VSS = -2.75V at codes C74A hex and 281C hex. Note 3: Steady-state change in any output with an 8V change in an adjacent output. Note 4: Settling during the first update for an 8V step. The output will settle to within the linearity specification on subsequent updates. Tested with an external sequencer clock frequency of 480kHz. Note 5: External clock mode with the external clock not toggling. Note 6: The output voltage is the sum of the DAC output and the voltage at GS. GS gain is measured at 4F2C hex. Note 7: The sequencer runs at fSEQ = fECLK/4. Maximum speed is limited by settling of the DAC and SHAs. Minimum speed is limited by acceptable droop and update time after a Burst Mode Update. Note 8: VDD rise to CS low = 500s maximum. Note 9: Guaranteed by gain-error test. Note 10: The serial interface is inactive. VIH = VLOGIC, VIL = 0V. Note 11: The serial interface is active. VIH = VLOGIC, VIL = 0V. 4 Maxim Integrated MAX5631/MAX5632/MAX5633 16-Bit DACs with 32-Channel Sample-and-Hold Outputs Typical Operating Characteristics (VDD = +10V, VSS = -4V, VREF = +2.5V, VGS = 0V, TA = +25C, unless otherwise noted.) -0.001 -0.003 -0.005 -0.007 -0.6 -1.0 -1.4 INPUT CODE INPUT CODE DIFFERENTIAL NONLINEARITY VS. TEMPERATURE OFFSET VOLTAGE VS. TEMPERATURE 0.6 -40 MAX5631 toc05 -15 10 35 60 -16 85 -15 10 35 60 GAIN ERROR VS. TEMPERATURE POSITIVE SUPPLY PSRR VS. FREQUENCY 0.100 0.010 85 -40 -80 -70 0 -15 10 35 TEMPERATURE (C) Maxim Integrated 60 85 35 60 85 -90 -80 -70 -60 -50 -40 -50 -40 -30 -30 -20 -20 -10 -10 0 -40 10 NEGATIVE SUPPLY PSRR VS. FREQUENCY PSRR (dB) PSRR (dB) CODE = C168 hex OFFSET CODE = 4F2C hex 0.01 -15 TEMPERATURE (C) -90 MAX5631 toc07 0.02 85 1 -60 0.03 60 0.0001 -40 TEMPERATURE (C) 0.04 35 0.001 TEMPERATURE (C) 0.05 10 CODE = 4F2C hex EXTERNAL CLOCK MODE NO CLOCK APPLIED 10 DROOP RATE (mV/s) -14 -20 -40 -15 100 -18 0.5 0.002 DROOP RATE vs. TEMPERATURE VDD = +8.55V VSS = -4V CODE = 4F2C hex -12 OFFSET VOLTAGE (mV) 0.7 0.004 TEMPERATURE (C) -10 MAX5631 toc04 0.8 0.006 0 4018 11769 19520 27271 35021 42723 58268 0.9 MAX5631 toc03 MAX5631 toc02 -0.2 4018 11769 19520 27271 35021 42723 58268 1.0 DIFFERENTIAL NONLINEARITY (LSB) 0.2 0.008 MAX5631 toc06 0.001 0.6 MAX5631 toc09 0.003 1.0 0.010 MAX5361 toc08 INTEGRAL NONLINEARITY (%) 0.005 1.4 DIFFERENTIAL NONLINEARITY (LSB) MAX5631 toc01 0.007 GAIN ERROR (%) INTEGRAL NONLINEARITY VS. TEMPERATURE DIFFERENTIAL NONLINEARITY vs. CODE INTEGRAL NONLINEARITY (%) INTEGRAL NONLINEARITY vs. CODE 0.01 0.1 1 FREQUENCY (kHz) 10 100 0 0.001 0.01 0.1 1 10 100 FREQUENCY (kHz) 5 MAX5631/MAX5632/MAX5633 16-Bit DACs with 32-Channel Sample-and-Hold Outputs Typical Operating Characteristics (continued) (VDD = +10V, VSS = -4V, VREF = +2.5V, VGS = 0V, TA = +25C, unless otherwise noted.) LOGIC SUPPLY CURRENT VS. LOGIC INPUT HIGH VOLTAGE 600 500 1000 34 SUPPLY CURRENT (mA) 700 36 MAX5631 toc11 LOGIC SUPPLY CURRENT (A) 800 SUPPLY CURRENT vs. TEMPERATURE 1200 MAX5631 toc10 LOGIC SUPPLY CURRENT (A) 900 800 600 400 5.25 28 ISS 26 INTERFACE INACTIVE 0 5.00 30 22 fSCLK = 20MHz INTERFACE INACTIVE 4.75 IDD 32 24 200 400 MAX5631 toc12 LOGIC SUPPLY CURRENT vs. LOGIC SUPPLY VOLTAGE 20 2.0 5.50 2.5 LOGIC SUPLY VOLTAGE (V) POSITIVE SETTLING TIME (8V STEP) 3.0 3.5 4.0 4.5 5.0 -40 -15 10 35 TEMPERATURE (C) NEGATIVE SETTLING TIME (8V STEP) POSITIVE SETTLING TIME (100mV STEP) MAX5631 toc14 MAX5631 toc13 85 MAX5631 toc15 3.5V 3.5V 3.5V ECLK ECLK ECLK 60 LOGIC INPUT HIGH VOLTAGE (V) 0 0 0 5V/div VOUT_ 50mV/div AC COUPLED VOUT_ 5V/div VOUT_ 1s/div 1s/div NEGATIVE SETTLING TIME (100mV STEP) 1s/div OUTPUT NOISE MAX5631 toc16 MAX5631 toc17 3.5V ECLK 0 OUT_ 1mV/div 50mV/div AC COUPLED VOUT_ 1s/div 6 250s/div Maxim Integrated MAX5631/MAX5632/MAX5633 16-Bit DACs with 32-Channel Sample-and-Hold Outputs Pin Description PIN NAME FUNCTION TQFP TQFN 1, 2 1, 2, 17, 34, 51, 68 N.C. 3 3 GS 4 4 VLDAC 5 5 RST Reset Input 6 6 CS Chip-Select Input 7 7 DIN Serial Data Input 8 8 SCLK 9 9 VLOGIC 10 10 IMMED 11 11 ECLK 12 12 CLKSEL 13 13 DGND Digital Ground 14 14 VLSHA +5V Sample-and-Hold Power Supply 15, 25, 40, 55, 62 15, 26, 42, 58, 65 AGND Analog Ground 16, 32, 46 16, 33, 48 VSS 17, 39, 48 18, 41, 50 VDD Positive Power Supply 18, 33, 49 19, 35, 52 CL Output Clamp Low Voltage 19 20 OUT0 Output 0 20 21 OUT1 Output 1 21 22 OUT2 Output 2 22 23 OUT3 Output 3 23 24 OUT4 Output 4 24 25 OUT5 Output 5 26 27 OUT6 Output 6 27 28 OUT7 Output 7 28 29 OUT8 Output 8 29 30 OUT9 Output 9 30 31 OUT10 Output 10 31, 47, 64 32, 49, 67 CH 34 36 OUT11 Output 11 35 37 OUT12 Output 12 36 38 OUT13 Output 13 37 39 OUT14 Output 14 38 40 OUT15 Output 15 41 43 OUT16 Output 16 42 44 OUT17 Output 17 43 45 OUT18 Output 18 44 46 OUT19 Output 19 45 47 OUT20 Output 20 Maxim Integrated No Connection. Not internally connected. Ground-Sensing Input +5V DAC Power Supply Serial Clock Input +5V Logic Power Supply Immediate Update Mode External Sequencer Clock Input Clock-Select Input Negative Power Supply Output Clamp High Voltage 7 MAX5631/MAX5632/MAX5633 16-Bit DACs with 32-Channel Sample-and-Hold Outputs Pin Description (continued) PIN NAME FUNCTION TQFP TQFN 50 53 OUT21 Output 21 51 54 OUT22 Output 22 52 55 OUT23 Output 23 53 56 OUT24 Output 24 54 57 OUT25 Output 25 56 59 OUT26 Output 26 57 60 OUT27 Output 27 58 61 OUT28 Output 28 59 62 OUT29 Output 29 60 63 OUT30 Output 30 61 64 OUT31 63 66 REF -- -- Output 31 Reference Voltage Input Exposed Pad (TQFN Only). Internally connected to GND. Connect to a large ground plane to maximize thermal performance. Not intended as a electrical connection point. EP CH OUT0 ECLK CLKSEL CLOCK SAMPLEAND-HOLD ARRAY R E G I S T E R SAMPLE DATA READY SEQUENCER OUT31 CL READ ENABLE SEQUENTIAL ADDRESS LAST ADDRESS CS SCLK DIN IMMED RST 2: 1 M U X ADDR SELECT SERIAL INTERFACE WRITE ENABLE 16 x 32 SRAM R E G I S T E R GAIN AND OFFSET CORRECTION 16-BIT DAC GS REF MAX5631 MAX5632 MAX5633 D[15:0] Figure 1. Functional Diagram 8 Maxim Integrated MAX5631/MAX5632/MAX5633 16-Bit DACs with 32-Channel Sample-and-Hold Outputs tCSH1 CS tCSHO tCSSO tCH tCSS1 tCL SCLK tDH tDS B23 DIN B22 B0 Figure 2. Serial Interface Timing Diagram Detailed Description Digital-to-Analog Converter The MAX5631/MAX5632/MAX5633 16-bit digital-to-analog converters (DAC) are composed of two matched sections. The four MSBs are derived through 15 identical matched resistors and the lower 12 bits are derived through a 12-bit inverted R-2R ladder. Sample-and-Hold Amplifiers The MAX5631/MAX5632/MAX5633 contain 32 buffered sample/hold circuits with internal hold capacitors. Internal hold capacitors minimize leakage current, dielectric absorption, feedthrough, and required board space. MAX5631/MAX5632/MAX5633 provide a very low 1mV/s droop rate. Output The MAX5631/MAX5632/MAX5633 include output buffers on each channel. The device contains output resistors in series with the buffer output (Figure 3) for ease of output filtering and capacitive load driving stability. Output loads increase the analog supply current (IDD and ISS). Excessively loading the outputs drastically increases power dissipation. Do not exceed the maximum power dissipation specified in the Absolute Maximum Ratings. The maximum output voltage range depends on the analog supply voltages available and the output clamp voltages (see Output Clamp). (VSS + 0.75V) VOUT _ (VDD - 2.4V) The device has a fixed theoretical output range determined by the reference voltage, gain, and midscale offset. The output voltage for a given input code is calculated with the following: code VOUT = x VREF x 5.2428 65535 (1.6214 x VREF ) + VGS where code is the decimal value of the DAC input code, VREF is the reference voltage, and VGS is the Table 1. Code Table DAC INPUT CODE MSB LSB 1111 1111 1111 1111 NOMINAL OUTPUT VOLTAGE (V) 1100 0111 0100 1010 6.15 Maximum output with VDD = 8.55V 1000 0000 0000 0000 2.5 Midscale output 9.0535 0100 1111 0010 1100 0 0010 1000 0001 1100 -2.0 0000 0000 0000 0000 -4.0535 Maxim Integrated VREF = +2.5V Full-scale output VOUT_ = 0. All outputs default to this code after power-up Minimum output with VSS = -2.75V Zero-scale output 9 MAX5631/MAX5632/MAX5633 16-Bit DACs with 32-Channel Sample-and-Hold Outputs voltage at the ground-sense input. With a 2.5V reference, the nominal endpoints are -4.0535V and +9.0535V (Table 1). Note that these are "virtual" internal endpoint voltages and cannot be reached with all combinations of negative and positive power-supply voltages. The nominal, useable DAC endpoint codes for the selected power supplies may be calculated as: lower endpoint code = 32768 - ((2.5V - (VSS + 0.75) / 200V) (result 0) upper endpoint code = 32768 + ((VDD - 2.4 - 2.5V) / 200V) (result 65535) The resistive voltage-divider formed by the output resistor (RO) and the load impedance (RL), scales the output voltage. Determine VOUT_ as follows: RL RL + RO VOUT _ = VCHOLD x scaling factor Scaling Factor = Ground Sense The MAX5631/MAX5632/MAX5633 include a groundsense input (GS), which allows the output voltages to be referenced to a remote ground. The voltage at GS is added to the output voltage with unity gain. Note that the resulting output voltage must be within the valid output voltage range set by the power supplies. Output Clamp The MAX5631/MAX5632/MAX5633 clamps the output between two externally applied voltages. Internal diodes at each channel restrict the output voltage to: (VCH + 0.7V) VOUT _ (VCL - 0.7V) The clamping diodes allow the MAX5631/MAX5632/ MAX5633 to drive devices with restricted input ranges. The diodes also allow the outputs to be clamped during power-up or fault conditions. To disable output clamping, connect CH to V DD and CL to V SS, setting the clamping voltages beyond the maximum output voltage range. Serial Interface The MAX5631/MAX5632/MAX5633 are controlled by an SPI, QSPI, and MICROWIRE-compatible 3-wire interface. Serial data is clocked into the 24-bit shift register in an MSB-first format, with the 16-bit DAC data preceding the 5-bit SRAM address, 2-bit control, and a fill 0 (Figure 4). The input word is framed by CS. The first VREF DAC DATA CH GAIN AND OFFSET 16-BIT DAC RO OUT_ AV = 1 CHOLD RL CL ONE OF 32 SHA CHANNELS GS Figure 3. Analog Block Diagram DATA D15 D14 D13 D12 D11 D10 D09 D08 D07 D06 D05 D04 D03 D02 D01 MSB ADDRESS D0 A4 A3 A2 A1 CONTROL A0 C1 C0 0 LSB Figure 4. Input Word Sequence 10 Maxim Integrated MAX5631/MAX5632/MAX5633 16-Bit DACs with 32-Channel Sample-and-Hold Outputs Table 2. Channel/Output Selection A4 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 A3 0 0 0 0 0 0 0 0 1 1 1 1 1 1 1 1 0 0 0 0 0 0 0 0 1 1 1 1 1 1 1 A2 0 0 0 0 1 1 1 1 0 0 0 0 1 1 1 1 0 0 0 0 1 1 1 1 0 0 0 0 1 1 1 A1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 A0 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 OUT0 selected OUT1 selected OUT2 selected OUT3 selected OUT4 selected OUT5 selected OUT6 selected OUT7 selected OUT8 selected OUT9 selected OUT10 selected OUT11 selected OUT12 selected OUT13 selected OUT14 selected OUT15 selected OUT16 selected OUT17 selected OUT18 selected OUT19 selected OUT20 selected OUT21 selected OUT22 selected OUT23 selected OUT24 selected OUT25 selected OUT26 selected OUT27 selected OUT28 selected OUT29 selected OUT30 selected 1 1 1 1 1 OUT31 selected rising edge of SCLK after CS goes low will clock in the MSB of the input word. When each serial word is complete, the value is stored in the SRAM at the address indicated and the control bits are saved. Note that data may be corrupted if CS is not held low for an integer multiple of 24 bits. All of the digital inputs include Schmitt-trigger buffers to accept slow-transition interfaces. Their switching threshold is compatible with TTL and most CMOS logic levels. Maxim Integrated OUTPUT Serial Input Data Format and Control Codes The 24-bit serial input format, shown in Figure 4, comprises of 16 data bits (D15-D0), five address bits (A4-A0), two control bits (C1, C0), and a fill zero. The address code selects the output channel as shown in Table 2. The control code configures the device as follows: 1) If C1 = 1, Immediate Update Mode is selected. If C1 = 0, Burst Mode is selected. 2) If C0 = 0, the internal sequencer clock is selected. If C0 = 1, the external sequencer clock is selected. This must be repeated with each data word to maintain external input. 11 MAX5631/MAX5632/MAX5633 16-Bit DACs with 32-Channel Sample-and-Hold Outputs The operating modes can also be selected externally through CLKSEL and IMMED. In the case where the control bit in the serial word and the external signal conflict, the signal that is a logic "1" is dominant. Modes of Operation The MAX5631/MAX5632/MAX5633 feature three modes of operation: 1) Sequence Mode 2) Immediate Update Mode 3) Burst Mode Table 3. Update Mode UPDATE MODE UPDATE TIME Immediate Update Mode 2/fSEQ Burst Mode 33/fSEQ Sequence Mode Sequence mode is the default operating mode. The internal sequencer continuously scrolls through the SRAM, updating each of the 32 SHAs. At each SRAM address location, the stored 16-bit DAC code is loaded to the DAC. Once settled, the DAC output is acquired by the corresponding SHA. Using the internal sequencer clock, the process typically takes 320s to update all 32 SHAs (10s per channel). Using an external sequencer clock the update process takes 128 clock cycles (four clock cycles per channel). Immediate Update Mode Immediate update mode is used to change the contents of a single SRAM location, and update the corresponding SHA output. In Immediate Update Mode, the selected output is updated before the sequencer resumes operation. Select Immediate Update Mode by driving either IMMED or C1 high. The sequencer is interrupted when CS is taken low. The input word is then stored in the proper SRAM address. The DAC conversion and SHA sample in progress are completed transparent to the serial bus activity. The SRAM location of the addressed channel is then modified with the new data. The DAC and SHA are updated with the new voltage. The sequencer then resumes scrolling at the interrupted SRAM address. This operation can take up to two cycles of the 10s sequencer clock. Up to one cycle is needed to allow the sequencer to complete the operation in progress before it is freed to update the new channel. An additional cycle is required to read the new data from memory, update the DAC, and strobe the sample-and-hold. The sequencer resumes scrolling from the location at which it was interrupted. Normal sequencing is suppressed while loading data, thus preventing other channels from being refreshed. Under conditions of extremely frequent Immediate Updates (i.e., 1000 successive updates), this can result in unacceptable droop. Figure 5 shows an example of an immediate update operation. In this example, data for channel 20 is loaded while channel 7 is being refreshed. The sequencer operation is interrupted, and no other channels are refreshed as long as CS is held low. Once CS returns high, and the remainder of an fSEQ period (if any) has expired, channel 20 is updated to the new data. Once channel 20 has been updated, the sequencer resumes normal operation at the interrupted channel 7. 1/fSEQ SHA ARRAY UPDATE SEQUENCE 1/fSEQ 1 2 3 7 SKIP 20 7 8 9 SHA ARRAY UPDATE SEQUENCE CHANNEL 20 UPDATED 7 SKIP SKIP SKIP 7 8 5 6 7 33 CYCLES TO UPDATE ALL CHANNELS CS INTERRUPTED CHANNEL REFRESHED LOAD ADDRESS 20 6 CS LOAD MULTIPLE ADDRESSES DIN DIN 24-BIT WORD Figure 5. Immediate Update Mode Timing Example 12 Figure 6. Burst Mode Timing Example Maxim Integrated MAX5631/MAX5632/MAX5633 16-Bit DACs with 32-Channel Sample-and-Hold Outputs Burst Mode Burst Mode allows multiple SRAM locations to be loaded at high speed. During Burst Mode, the output voltages are not updated until the data burst is complete and control returns to the sequencer. Select Burst Mode by driving both IMMED and C1 low. The sequencer is interrupted when CS is taken low. All or part of the memory can be loaded while CS is low. Each data word is loaded into its specified SRAM address. The DAC conversion and SHA sample in progress are completely transparent to the serial bus activity. When CS is taken high, the sequencer resumes scrolling at the interrupted SRAM address. New values are updated when their turn comes up in the sequence. After Burst Mode is used, it is least one full sequencer loop occur before the serial port is ensures that all outputs are sequencer is interrupted. recommended that at (320s) is allowed to accessed again. This updated before the Figure 6 shows an example of a burst mode operation. As with the immediate update example, CS falls while channel 7 is being refreshed. Data for multiple channels is loaded, and no channels are refreshed as long as CS remains low. Once CS returns high, sequencing resumes with channel 7 and continues normal refresh operation. Thirty-three fSEQ cycles are required before all channels have been updated. External Sequencer Clock An external clock may be used to control the sequencer, altering the output update rate. The sequencer runs at 1/4 the frequency of the supplied clock (ECLK). The external clock option is selected by driving either C0 or CLKSEL high. When CLKSEL is asserted, the internal clock oscillator is disabled. This feature allows synchronizing the sequencer to other system operations, or shutting down of the sequencer altogether during high-accuracy system measurements. The low 1mV/s droop of these devices ensures that no appreciable degradation of the output voltages occurs, even during extended periods of time when the sequencer is disabled. Maxim Integrated Power-On Reset A power-on reset (POR) circuit sets all channels to 0V (code 4F2C hex) in sequence, requiring 320s. This prevents damage to downstream ICs due to arbitrary reference levels being presented following system power-up. This same function is available by driving RST low. During the reset operation, the sequencer is run by the internal clock, regardless of the state of CLKSEL. The reset process cannot be interrupted, serial inputs will be ignored until the entire reset process is complete. Applications Information Power Supplies and Bypassing Grounding and power-supply decoupling strongly influence device performance. Digital signals may couple through the reference input, power supplies, and ground connection. Proper grounding and layout can reduce digital feedthrough and crosstalk. At the device level, a 0.1F capacitor is required for the VDD, VSS, and VL_ pins. They should be placed as close to the pins as possible. More substantial decoupling at the board level is recommended and is dependent on the number of devices on the board (Figure 7). The MAX5631/MAX5632/MAX5633 have three separate +5V logic power supplies, VLDAC, VLOGIC, and VLSHA. VLDAC powers the 16-bit digital-to-analog converter, VLSHA powers the control logic of the SHA array, and VLOGIC powers the serial interface, sequencer, internal clock and SRAM. Additional filtering of V LDAC and VLSHA improves the overall performance of the device. Chip Information PROCESS: BiCMOS Package Information For the latest package outline information and land patterns (footprints), go to www.maximintegrated.com/packages. Note that a "+", "#", or "-" in the package code indicates RoHS status only. Package drawings may show a different suffix character, but the drawing pertains to the package regardless of RoHS status. PACKAGE TYPE PACKAGE CODE OUTLINE NO. LAND PATTERN NO. 64 TQFP C64+8 21-0083 90-0141 68 TQFN-EP T6800+3 21-0142 90-0100 13 MAX5631/MAX5632/MAX5633 16-Bit DACs with 32-Channel Sample-and-Hold Outputs +10V +5V 0.1F 0.1F VLOGIC VLDAC VDD VLSHA REF +2.5V OUT0 GS OUT1 CS DIN MAX5631 MAX5632 MAX5633 SCLK IMMED CLKSEL ECLK RST OUT31 AGND DGND VSS CL 0.1F -4V Figure 7. Typical Operating Circuit N.C. 1 N.C. 2 GS 3 52 CL 53 OUT21 54 OUT22 55 OUT23 56 OUT24 57 OUT25 58 AGND 59 OUT26 60 OUT27 61 OUT28 62 OUT29 63 OUT30 64 OUT31 65 AGND 66 VREF 68 N.C. TOP VIEW 67 CH Pin Configurations (continued) 51 N.C. 50 VDD + 49 CH 48 VSS VLDAC 4 47 OUT20 RST 5 CS 6 DIN 7 46 OUT19 45 OUT18 SCLK 8 VLOGIC IMMED ECLK CLKSEL 44 OUT17 9 43 OUT16 MAX5631 MAX5632 MAX5633 10 11 42 AGND 41 VDD 12 40 OUT15 DGND 13 39 OUT14 VLSHA 14 38 OUT13 37 OUT12 AGND 15 VSS 16 N.C. 17 36 OUT11 34 33 32 31 OUT10 CH VSS N.C. OUT7 28 OUT8 29 OUT9 30 OUT5 25 AGND 26 OUT6 27 OUT2 22 OUT3 23 OUT4 24 CL 19 OUT0 20 OUT1 21 VDD 18 35 CL TQFN-EP 14 Maxim Integrated MAX5631/MAX5632/MAX5633 16-Bit DACs with 32-Channel Sample-and-Hold Outputs Revision History REVISION NUMBER REVISION DATE 0 10/01 Initial release 3 1/05 Updated the operating temperature range in the Ordering Information and updated the Typical Operating Characteristics. 4 9/12 Removed leaded options and added lead-free notation in Ordering Information. DESCRIPTION PAGES CHANGED -- 1, 2, 6 1 Maxim Integrated cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim Integrated product. No circuit patent licenses are implied. Maxim Integrated reserves the right to change the circuitry and specifications without notice at any time. The parametric values (min and max limits) shown in the Electrical Characteristics table are guaranteed. Other parametric values quoted in this data sheet are provided for guidance. Maxim Integrated 160 Rio Robles, San Jose, CA 95134 USA 1-408-601-1000 ________________________________ 15 (c) 2012 Maxim Integrated Products, Inc. Maxim Integrated and the Maxim Integrated logo are trademarks of Maxim Integrated Products, Inc.