19-0255; Rev 2; 4/94 CMOS, High-Speed, 8-Bit ADCs with Multiplexer ________________________Applications Digital Signal Processing High-Speed Data Acquisition Telecommunications High-Speed Servo Control Audio Instrumentation ____________________________Features One-Chip Data Acquisition System Four or Eight Analog Input Channels 2.5s per Channel Conversion Time Internal 2.5V Reference (MAX154/MAX158 only) Built-In Track/Hold Function 1/2LSB Error Specification Single +5V Supply Operation No External Clock New Space-Saving SSOP Package ______________Ordering Information TEMP. RANGE PART PIN-PACKAGE ERROR (LSB) MX7824LN 0C to +70C 24 Narrow Plastic DIP 1/2 MX7824KN 0C to +70C 24 Narrow Plastic DIP 1 MX7824LCWG 0C to +70C 24 Wide SO 1/2 MX7824KCWG 0C to +70C 24 Wide SO MX7824LCAG 0C to +70C 24 SSOP MX7824KCAG 0C to +70C 24 SSOP Ordering Information continued on last page. 1 1/2 1 __________________________________________________________Pin Configurations TOP VIEW AIN4 1 24 VDD AIN3 2 23 NC AIN2 3 22 A0 AIN1 4 TP (REF OUT) 5 21 A1 MAX154 MX7824 20 DB7 AIN6 1 28 AIN7 AIN5 2 27 AIN8 AIN4 3 26 VDD AIN3 4 25 A0 AIN2 5 AIN1 6 MAX158 MX7828 24 A1 23 A2 19 DB6 TP (REF OUT) 7 22 DB7 18 DB5 DB0 8 21 DB6 DB2 8 17 DB4 DB1 9 20 DB5 DB3 9 16 CS DB2 10 19 DB4 RD 10 15 RDY DB3 11 18 CS INT 11 14 VREF+ RD 12 17 RDY 13 VREF- INT 13 16 VREF+ GND 14 15 VREF- DB0 6 DB1 7 GND 12 DIP/SO/SSOP DIP/SO/SSOP ( ) ARE FOR MAX154/MAX158 ONLY. ________________________________________________________________ Maxim Integrated Products Call toll free 1-800-998-8800 for free samples or literature. 1 MX7824/MX7828 _______________General Description The MAX154/MAX158 and MX7824/MX7828 are highspeed, multi-channel analog-to-digital converters (ADCs). The MAX154 and MX7824 have four analog input channels, while the MAX158 and MX7828 have eight channels. Conversion time for all devices is 2.5s. The MAX154/MAX158 also feature a 2.5V on-chip reference, forming a complete high-speed data acquisition system. All four converters include a built-in track/hold, eliminating the need for an external track/hold with many input signals. The analog input range is 0V to +5V, although the ADC operates from a single +5V supply. Microprocessor interfaces are simplified by the ADC's ability to appear as a memory location or I/O port without the need for external logic. The data outputs use latched, three-state buffer circuitry to allow direct connection to a microprocessor data bus or system input port. The MX7824 and MX7828 are pin compatible with Analog Devices' AD7824 and AD7828. The MAX154 and MAX158, which feature internal references, are also compatible with these products. MX7824/MX7828 CMOS, High-Speed, 8-Bit ADCs with Multiplexer ABSOLUTE MAXIMUM RATINGS Supply Voltage, VDD to GND ........................................0V, +10V Voltage at Any Other Pins......................GND - 0.3V, VDD + 0.3V Output Current (REF OUT)..................................................30mA Power Dissipation (any package) to +75C ....................450mW Derate above +25C by ..............................................6mW/C Operating Temperature Ranges MX7824, MX7828 KN/LN/KCW_/LCW_ ............................................0C to +70C BQ/CQ .............................................................-40C to +85C TQ/UQ............................................................-55C to +125C Storage Temperature Range .............................-65C to +160C Lead Temperature (soldering, 10sec) .............................+300C 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 = +5V, VREF+ = +5V, VREF- = GND, Mode 0, TA = TMIN to TMAX, unless otherwise noted.) PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS ACCURACY Resolution 8 Bits MAX15_A, MX782_L/C/U MAX15_B, MX782_K/B/T Total Unadjusted Error (Note 1) No Missing Codes Resolution 1/2 1 LSB 1/4 LSB 8 Bits Channel to Channel Mismatch REFERENCE INPUT Reference Resistance 1 4 k VREF+ Input Voltage Range VREF- VDD V VREF- Input Voltage Range GND VREF+ V REFERENCE OUTPUT--MAX154/MAX158 Only (Note 2) Output Voltage 2.50 2.53 V Load Regulation REF OUT IL = 0mA to 10mA, TA = +25C -6 -10 mV Power-Supply Sensitivity VDD 5%, TA = +25C 1 3 mV MAX15_C 40 70 MAX15_E 40 70 MAX15_M 60 100 Temperature Drift (Note 3) Output Noise TA = +25C 2.47 eN 200 Capacitive Load ppm/C V/rms 0.01 F ANALOG INPUT Analog Input Voltage Range AINR Analog Input Capacitance CAIN Analog Input Current IAIN VREF- VREF+ 45 Any channel, AIN = 0V to 5V Slew Rate, Tracking SR ---- ---- LOGIC INPUTS ( RD , CS , A0, A1, A2) 0.7 V pF 3 A 0.157 V/s Input High Voltage VINH Input Low Voltage VINL 0.8 V Input High Current IINH 1 A Input Low Current IINL -1 A Input Capacitance (Note 4) CIN 8 pF 2 2.4 V 5 _______________________________________________________________________________________ CMOS, High-Speed, 8-Bit ADCs with Multiplexer MX7824/MX7828 ELECTRICAL CHARACTERISTICS (VDD = +5V, VREF+ = +5V, VREF- = GND, Mode 0, TA = TMIN to TMAX, unless otherwise noted.) PARAMETER SYMBOL CONDITIONS MIN VOH -- ---- DB0-DB7, INT; IOUT = -360A 4.0 VOL -- ---- DB0-DB7, INT; RDY TYP MAX UNITS LOGIC OUTPUTS Output High Voltage Output Low Voltage Three-State Output Current Output Capacitance (Note 4) V IOUT = 1.6mA 0.4 IOUT = 2.6mA 0.4 DB0-DB7, RDY; VOUT = 0V to VDD COUT 5 V 3 A 8 pF POWER SUPPLY Supply Voltage VDD Supply Current IDD 5V 5% for specified performance ---- ---- CS = RD = 2.4V PSS VDD = 5% 4.75 Power Dissipation Power-Supply Sensitivity Note 1: Note 2: Note 3: Note 4: 5.25 V 15 mA 25 75 mW 1/16 1/4 LSB Total unadjusted error includes offset, full-scale, and linearity errors. Specified with no external load unless otherwise noted. Temperature drift is defined as change in output voltage from +25C to TMIN or TMAX divided by (25 - TMIN) or (TMAX - 25). Guaranteed by design. TIMING CHARACTERISTICS (Note 5) (VDD = +5V, VREF+ = +5V, VREF- = GND, Mode 0, TA = TMIN to TMAX, unless otherwise noted.) PARAMETER SYMBOL TA = +25C CONDITIONS MIN ---- ---- CS to RD Setup Time ---- ---- CS to RD Hold Time Multiplexer Address Setup Time Multiplexer Address Hold Time ---- CS to RDY Delay Conversion Time (Mode 0) ---- Data Access Time After RD Data Access Time -- ---- After INT, Mode 0 ---- -- ---- RD to INT Delay (Mode 1) Data Hold Time Delay Time Between Conversions ---- RD Pulse Width (Mode 1) TYP MAX MAX15_ _C/E MX782_K/L/B/C MIN MAX MAX15_ _M MX782_T/U MIN UNITS MAX tCSS 0 0 0 ns tCSH 0 0 0 ns tAS 0 0 0 ns 30 tAH 40 ns 40 2.0 85 60 2.4 110 60 2.8 120 ns s ns (Note 6) 20 50 60 70 ns CL = 50pF 40 75 100 100 ns 60 70 70 ns CL = 50pF, RL = 5k tACC2 tINTH tDH 35 30 1.6 tRDY tCRD tACC1 (Note 6) (Note 7) tP 500 tRD 60 500 600 80 600 500 80 ns 400 ns Note 5: All input control signals are specified with tR = tF = 20ns (10% to 90% of +5V) and timed from a 1.6V voltage level. Note 6: Measured with load circuits of Figure 1 and defined as the time required for an output to cross 0.8V or 2.4V. Note 7: Defined as the time required for the data lines to change 0.5V when loaded with the circuits of Figure 2. _______________________________________________________________________________________ 3 __________________________________________Typical Operating Characteristics (TA = +25C, unless otherwise noted.) OUTPUT CURRENT vs. TEMPERATURE VDD = 5V 2.500 2.490 LINEARITY ERROR (LSB) 16 OUTPUT CURRENT (mA) 2.510 2.0 MX7824/28-2 20 MX7824/28-1 2.520 ACCURACY vs. DELAY BETWEEN CONVERSIONS (tp) ISOURCE VOUT = 2.4V 12 8 ISINK VOUT = 0.4V 4 0 50 -100 150 100 0.5 -50 0 50 300 150 100 400 500 ACCURACY vs. VREF (VREF = VREF+ - VREF-) 600 700 8 IDD - SUPPLY CURRENT (mA) MX7824/28-4 VDD = 5V 1.5 1.0 0.5 0 7 VDD = 5.25V 6 5 VDD = 5V 4 VDD = 4.75V 3 2 0 1 2 3 4 5 -100 VREF (V) -50 0 50 100 150 AMBIENT TEMPERATURE (C) +5V +5V 3k DBN DBN 100pF 100pF DGND DGND b. High-Z to VOL Figure 1. Load Circuits for Data-Access Time Test 4 3k DBN DBN a. High-Z to VOH 900 POWER-SUPPLY CURRENT vs. TEMPERATURE (NOT INCLUDING REFERENCE LADDER) 2.0 3k 800 tp (ns) AMBIENT TEMPERATURE (C) AMBIENT TEMPERATURE (C) LINEARITY ERROR (LSB) 1.0 MX7824/28-5 -50 VDD = 5V VREF = 5V 1.5 0 0 2.480 MX7824/28-3 REFERENCE TEMPERATURE DRIFT (MAX154/MAX158 ONLY) REF OUT VOLTAGE (V) MX7824/MX7828 CMOS, High-Speed, 8-Bit ADCs with Multiplexer 3k 10pF 10pF DGND a. VOH to High-Z DGND b. VOL to High-Z Figure 2. Load Circuits for Data-Hold Time Test _______________________________________________________________________________________ CMOS, High-Speed, 8-Bit ADCs with Multiplexer PIN PIN NAME FUNCTION MAX154 MX7824 NAME FUNCTION MAX158 MX7828 1 AIN4 Analog Input Channel 4 1 AIN6 Analog Input Channel 6 2 AIN3 Analog Input Channel 3 2 AIN5 Analog Input Channel 5 3 AIN2 Analog Input Channel 2 3 AIN4 Analog Input Channel 4 4 AIN1 Analog Input Channel 1 4 AIN3 Analog Input Channel 3 5 REF OUT TP Reference Output (2.5V) for MAX154. Test point for MX7824. Do not connect. 5 AIN2 Analog Input Channel 2 6 AIN1 Analog Input Channel 1 6 DBO Three-State Data Output, bit 0 (LSB) 7 DB1 Three-State Data Output, bit 1 7 REF OUT TP 8 DB2 Three-State Data Output, bit 2 8 DB0 Three-State Data Output, bit 0 (LSB) 9 DB3 Three-State Data Output, bit 3 ---- Read Input. RD controls conversions and data access. See Digital Interface section. Interrupt Output. INT going low indicates the completion of a conversion. See Digital Interface section. 9 DB1 Three-State Data Output, bit 1 10 DB2 Three-State Data Output, bit 2 11 DB3 12 ---- RD Three-State Data Output, bit 3 ---- Read Input. RD controls conversions and data access. See Digital Interface section. Ground Lower Limit of Reference Span. Sets the zero-code voltage. Range: GND to VREF+. Upper Limit of Reference Span. Sets the full-scale input voltage. Range: VREF- to VDD. 13 INT Interrupt Output. INT going low indicates the completion of a conversion. See Digital Interface section. 14 GND 15 VREF- Ready Output. Open-drain output with no active pull-up device. Goes low ---- when CS goes low and high impedance at the end of a conversion. ---- Chip-Select Input. CS must be low for the device to be selected. 16 VREF+ 17 RDY 18 ---- CS 10 ---- RD 11 INT 12 GND 13 VREF- 14 VREF+ 15 RDY Reference Output (2.5V) for MAX158. Test point for MX7828. Do not connect. Ground Lower Limit of Reference Span. Sets the zero-code voltage. Range: GND to VREF+. Upper Limit of Reference Span. Sets the full-scale input voltage. Range: VREF- to VDD. Ready Output. Open-drain output with no active pull-up device. Goes low ---- when CS goes low and high impedance at the end of a conversion. ---- Chip-Select Input. CS must be low for the device to be selected. 16 ---- CS 17 DB4 Three-State Data Output, bit 4 18 DB5 Three-State Data Output, bit 5 19 DB6 Three-State Data Output, bit 6 19 DB4 Three-State Data Output, bit 4 20 DB7 Three-State Data Output, bit 7 (MSB) 20 DB5 Three-State Data Output, bit 5 21 A1 Channel Address 1 Input 21 DB6 Three-State Data Output, bit 6 22 A0 Channel Address 0 Input 22 DB7 Three-State Data Output, bit 7 (MSB) 23 NC No Connect 23 A2 Channel Address 2 Input 24 VDD Power-Supply Voltage, +5V 24 A1 Channel Address 1 Input 25 A0 Channel Address 0 Input 26 VDD Power-Supply Voltage, +5V 27 AIN8 Analog Input Channel 8 28 AIN7 Analog Input Channel 7 _______________________________________________________________________________________ 5 MX7824/MX7828 _____________________________________________________________Pin Descriptions MX7824/MX7828 CMOS, High-Speed, 8-Bit ADCs with Multiplexer _______________Detailed Description ___________________Digital Interface Converter Operation The MAX154/MAX158 and MX7824/MX7828 use only Chip Select (CS) and Read (RD) as control inputs. A READ operation, taking CS and RD low, latches the multiplexer address inputs and starts a conversion (Table 1). The MAX154/MAX158 and MX7824/MX7828 use what is commonly called a "half-flash" conversion technique (Figure 3). Two 4-bit flash ADC sections are used to achieve an 8-bit result. Using 15 comparators, the upper 4-bit MS (most significant) flash ADC compares the unknown input voltage to the reference ladder and provides the upper four data bits. An internal DAC uses the MS bits to generate an analog signal from the first flash conversion. A residue voltage representing the difference between the unknown input and the DAC voltage is then compared to the reference ladder by 15 LS (least significant) flash comparators to obtain the lower four output bits. Table 1. Truth Table for Input Channel Selection MAX154/MX7824 A1 A0 0 0 1 1 0 1 0 1 Operating Sequence The operating sequence is shown in Figure 4. A conversion is initiated by a falling edge of RD and CS. The comparator inputs track the analog input voltage for approximately 1s. After this first cycle, the MS flash result is latched into the output buffers and the LS conversion begins. INT goes low approximately 600ns later, indicating the end of the conversion, and that the lower four bits are latched into the output buffers. The data can then be accessed using the CS and RD inputs. AIN1 REF OUT** 0 0 0 0 0 0 1 1 0 1 0 1 AIN1 AIN2 AIN3 AIN4 1 1 1 1 0 0 1 1 0 1 0 1 AIN5 AIN6 AIN7 AIN8 DB7 DB6 4-BIT FLASH ADC (4MSB) VREF- VREF+ 16 2.5V REF *MAX154/MX7824 - 4-Channel Mux MAX158/MX7828 - 8-Channel Mux ** REF OUT on MAX154/MAX158 only DB5 DB4 THREESTATE DRIVERS 4-BIT DAC MUX* AIN8 A1 A2 DB3 DB2 DB1 4-BIT FLASH ADC (4LSB) ADDRESS LATCH DECODE A0 DB0 TIMING AND CONTROL CIRCUITRY RDY CS INT RD Figure 3. Functional Diagram 6 SELECTED CHANNEL There are two interface modes, which are determined by the length of the RD input. Mode 0, implemented by keeping RD low until the conversion ends, is designed for microprocessors that can be forced into a WAIT state. In this mode, a conversion is started with a READ operation (taking CS and RD low), and data is read when the conversion ends. Mode 1, on the other hand, VREF+ AIN4 MAX158/MX7828 A2 A1 A0 _______________________________________________________________________________________ CMOS, High-Speed, 8-Bit ADCs with Multiplexer 500ns 1000ns SETUP TIME REQUIRED BY THE INTERNAL COMPARATORS PRIOR TO STARTING CONVERSION 600ns VIN IS SAMPLED AND THE FOUR MSBs ARE LATCHED VIN IS TRACKED BY INTERNAL COMPARATORS There are two status outputs: Interrupt (INT) and Ready (RDY). RDY, an open-drain output (no internal pull-up device), is connected to the processor's READY/WAIT input. RDY goes low on the falling edge of CS and goes high impedance at the end of the conversion, when the conversion result appears on the data outputs. If the RDY output is not required, its external pull-up resistor can be omitted. INT goes low when the conversion is complete and returns high on the rising edge of CS or RD. Interface Mode 1 Figure 4. Operating Sequence does not require microprocessor WAIT states. A READ operation simultaneously initiates a conversion and reads the previous conversion result. Interface Mode 0 Figure 5 shows the timing diagram for Mode 0 operation. This is used with microprocessors that have WAIT state capability, whereby a READ instruction is extended to accommodate slow-memory devices. Taking CS and RD low latches the analog multiplexer address and starts a conversion. Data outputs DB0-DB7 remain in the high-impedance condition until the conversion is complete. Mode 1 is designed for applications where the microprocessor is not forced into a WAIT state. Taking CS and RD low latches the multiplexer address and starts a conversion (Figure 6). Data from the previous conversion is immediately read from the outputs (DB0-DB7). INT goes high at the rising edge of CS or RD and goes low at the end of the conversion. A second READ operation is required to read the result of this conversion. The second READ latches a new multiplexer address and starts another conversion. A delay of 2.5s must be allowed between READ operations. RDY goes low on the falling edge of CS and goes high impedance at the rising edge of CS. If RDY is not needed, its external pull-up resistor can be omitted. CS tCSH tCSS tCSS RD tP tAS tAS ANALOG CHANNEL ADDRESS ADDR VALID ADDR VALID tAH RDY tRDY INT tINTH tCRD tACC2 HIGH IMPEDANCE DATA tDH DATA VALID Figure 5. Mode 0 Timing Diagram _______________________________________________________________________________________ 7 MX7824/MX7828 RD INT GOING LOW INDICATES THAT CONVERSION IS COMPLETE AND THAT DATA CAN BE READ MX7824/MX7828 CMOS, High-Speed, 8-Bit ADCs with Multiplexer CS tRD tCSS tCSH tCSS tCSH tRD RD tP tAS tAS ANALOG CHANNEL ADDRESS ADDR VALID ADDR VALID tAH tAH RDY tRDY tRDY tCRD tINTH INT tACCI tINTH tDH tDH tACCI OLD DATA DATA NEW DATA Figure 6. Mode 1 Timing Diagram _____________Analog Considerations OUTPUT CODE Reference and Input The VREF+ and VREF- inputs of the converter define the zero and the full-scale of the ADC. In other words, the voltage at VREF- is equal to the input voltage that produces an output code of all zeros, and the voltage at VREF+ is equal to input voltage that produces an output code of all ones (Figure 7). Figure 8 shows some possible reference configurations. For the MAX154/MAX158, a 0.01F bypass capacitor to GND should be used to reduce the highfrequency output impedance of the internal reference. Larger capacitors should not be used, as this degrades the stability of the reference buffer. The 2.5V reference output is with respect to the GND pin. FULL-SCALE TRANSITION 11111111 11111110 11111101 1LSB = F8 = VREF+ - VREF256 256 00000011 00000010 VREF+ 00000001 Bypassing A 47F electrolytic and 0.1F ceramic capacitor should be used to bypass the VDD pin to GND. These capacitors must have minimum lead length, since excess lead length may contribute to conversion errors and instability. If the reference inputs are driven by long lines, they should be bypassed to GND with 0.1F capacitors at the reference input pins. 8 00000000 VREF- 1 2 3 FS AIN INPUT VOLTAGE (IN TERMS OF LSBs) Figure 7. Transfer Function _______________________________________________________________________________________ FS-1LSB CMOS, High-Speed, 8-Bit ADCs with Multiplexer VIN AINx(-) GND VDD +5V REF OUT 0.1F 47F Input Current MAX154 MAX158 VREF+ 0.01F VREF- Figure 8a. Internal Reference (MAX154/MAX158 only) AINx(+) VIN AINx(-) GND VDD +5V 0.1F 2.5V 47F MX584 MX7824 MX7828 VREF+ VREF- Figure 8b. External Reference +2.5V Full-Scale AINx(+) VIN AINx(-) GND Input Filtering MAX154 MAX158 VREF+ MX7824 MX7828 VDD +5V 0.1F 47F The converters' analog inputs behave somewhat differently from conventional ADCs. The sampled data comparators take varying amounts of current from the input, depending on the cycle they are in. The equivalent circuit of the converter is shown in Figure 9a. When the conversion starts, AIN(n) is connected to the MS and LS comparators. Thus, AIN(n) is connected to thirty-one 1pF capacitors. To acquire the input signal in approximately 1s, the input capacitors must charge to the input voltage through the on-resistance of the multiplexer (about 600) and the comparator's analog switches (2k to 5k per comparator). In addition, about 12pF of stray capacitance must be charged. The input can be modeled as an equivalent RC network shown in Figure 9b. As RS (source impedance) increases, the capacitors take longer to charge. Since the length of the input acquisition time is internally set, large source resistances (greater than 100) will cause settling errors. The output impedance of an opamp is its open-loop output impedance divided by the loop gain at the frequency of interest. It is important that the amplifier driving the converter input have sufficient loop gain at approximately 1MHz to maintain low output impedance. VREF- Figure 8c. Power Supply as Reference The transients in the analog input caused by the sampled data comparators do not degrade the converter's performance, since the ADC does not "look" at the input when these transients occur. The comparator's outputs track the input during the first 1s of the conversion, and are then latched. Therefore, at least 1s will be provided to charge the ADC's input capacitance. It is not necessary to filter these transients with an external capacitor on the AIN terminals. Sinusoidal Inputs * Current path must still exist from VIN(-) to Ground AINx(+) VIN GND VDD +5V 0.1F VREF+ 47F 2.5V VREF- AINx(-) * MAX154 MAX158 MX7824 MX7828 The MAX154/MAX158 and MX7824/MX7828 can measure input signals with slew rates as high as 157mV/s to the rated specifications. This means that the analog input frequency can be as high as 10kHz without the aid of an external track/hold. The maximum sampling rate is limited by the conversion time (typical tCRD = 2s) plus the time required between conversions (tp = 500ns). It is calculated as: fMAX = 1 1 = = 400kHz tCRD + tp (2.0 + 0.5) s Figure 8d. Inputs Not Referenced to GND _______________________________________________________________________________________ 9 MX7824/MX7828 AINx(+) MX7824/MX7828 CMOS, High-Speed, 8-Bit ADCs with Multiplexer fMAX permits a maximum sampling rate of 50kHz per channel when using the MAX158/MX7828 and 100kHz per channel when using the MAX154/MX7824. These rates are well above the Nyquist requirement of 20kHz sampling rate for a 10kHz input bandwidth. Bipolar Input Operation The circuit in Figure 10a can be used for bipolar input operation. The input voltage is scaled by an amplifier so that only positive voltages appear at the ADC's inputs. An external reference should be used for the MX7824/ MX7828, but is not needed with the MAX154/MAX158. The analog input range is 4V and the output code is complementary offset binary. The ideal input/output characteristic is shown in Figure 10b. 3.57k 11.5 VIN 0.01F CS AIN1 10.0k MAX154 MAX158 16.2k RDY RD 0.01F VREF+ INT REF OUT +5V VDD DB0-DB7 VREF47F 0.1F RS AIN1 VIN CS 2pF RON RMUX CS 12pF GND ONLY CHANNEL 1 SHOWN 1pF 1pF * * * 15 LSB COMPARATORS TO LS LADDER Figure 10a. Bipolar 4V Input Operation RON 1pF 1pF * * * 16 MSB COMPARATORS TO MS LADDER FS = 8V 1LSB = FS / 256 11111111 11111110 11111101 Figure 9a. Equivalent Input Circuit 10000010 10000001 +FS 2 10000000 01111111 RS VIN AIN1 B MUX 600 CS1 2pF 01111110 RON 350 CS2 2pF -FS + 1LSB 2 00000010 00000001 32pF 00000000 0V AIN INPUT VOLTAGE (LSBs) Figure 9b. RC Network Model 10 Figure 10b. Transfer Function for 4V Input Operation ______________________________________________________________________________________ CMOS, High-Speed, 8-Bit ADCs with Multiplexer ADDRESS BUS VDD A0 EN MREQ ADDRESS DECODE A0 A1 A2* BANDPASS FILTER 1 6 BANDPASS FILTER 2 5 AIN2 AIN1 5V ZBO MX7824/MX7828 +5V 26 A15 MAX154 MAX158 RDY MX7824 MX7828 RD CS 5k WAIT RD 18 RD 12 MAX158 MX7828 AMP DB0-DB7 BANDPASS FILTER 7 28 A2 BANDPASS FILTER 8 +5V DATA AIN7 DB0-DB7 DATA BUS D0-D7 SPEECH INPUT CS 27 AIN8 16 VREF+ VREF15 A1 A0 23 24 25 GND 14 *A2 ON MAX158/MX7828 ONLY. Figure 12. Speech Analysis Using Real-Time Filtering Figure 11. Simple Mode 0 Interface SAMPLE PULSE +5V 24 VDD 16 CS 4 AIN1 3 AIN2 2 1 14 13 12 AIN3 AIN4 +15V 18 VDD 10 RD INT 11 15 VREF 4 WR MAX154 MX7824 VOUT A 2 MX7226 DB0-DB7 VOUT B 1 VOUT C DB0-DB7 VREF+ VOUT D VREF- A1 A0 GND 21 16 A1 22 17 A0 DGND AGND 20 19 6 5 VSS 3 A0 A1 Figure 13. 4-Channel Fast Sample and Infinite Hold ______________________________________________________________________________________ 11 MX7824/MX7828 CMOS, High-Speed, 8-Bit ADCs with Multiplexer _Ordering Information (continued) PART TEMP. RANGE PIN-PACKAGE MX7824LEAG -40C to +85C 24 SSOP ERROR (LSB) MX7824KEAG -40C to +85C 24 SSOP -40C to +85C 24 CERDIP 1/2 MX7824BQ MX7824UQ MX7824TQ -40C to +85C -55C to +125C -55C to +125C 24 CERDIP 24 CERDIP 24 CERDIP 1 1/2 1 MX7828LN MX7828KN MX7828LCWI 0C to +70C 0C to +70C 0C to +70C 28 Plastic DIP 28 Plastic DIP 28 Wide SO 1/2 1 1/2 MX7828KCWI 0C to +70C 28 Wide SO MX7828LCAI 0C to +70C 28 SSOP 1/2 MX7828KCAI 0C to +70C 28 SSOP 1 MX7828LP 0C to +70C 28 PLCC 1/2 0C to +70C 28 PLCC 1 -40C to +85C 28 SSOP 1/2 MX7828KP AIN4 AIN6 AIN8 (N.C.) (AIN2) (AIN4) AIN3 AIN5 AIN7 (N.C.) (AIN1) (AIN3) 1/2 MX7824CQ MX7828LEAI ___________________Chip Topography VDD A0 1 1 MX7828KEAI -40C to +85C 28 SSOP MX7828CQ -40C to +85C 28 CERDIP 1/2 1 MX7828BQ -40C to +85C 28 CERDIP 1 MX7828UQ -55C to +125C 28 CERDIP 1/2 MX7828TQ -55C to +125C 28 CERDIP 1 A1 A2 (N.C.) AIN2 (N.C.) AIN1 (N.C.) TP (REF OUT) 0.127" (3.228mm) DB7 DB0 DB6 DB1 DB5 DB2 DB4 DB3 CS A0 GND VREF+ INT VREF- ADY 0.124" (3.150mm) ( ) ARE FOR MAX154/MX7824 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. 12 __________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 (408) 737-7600 (c) 1995 Maxim Integrated Products Printed USA is a registered trademark of Maxim Integrated Products.