AFV09P35004GNR3 - FREESCALE

AD7870/AD7875/AD7876

FEATURES

Complete Monolithic 12-Bit ADC with:

2 ms Track/Hold Amplifier

8 ms A/D Converter

On-Chip Reference

Laser-Trimmed Clock

Parallel, Byte and Serial Digital Interface

72 dB SNR at 10 kHz Input Frequency

(AD7870, AD7875)

57 ns Data Access Time

Low Power: –60 mW typ

Variety of Input Ranges:

63 V for AD7870

0 V to +5 V for AD7875

610 V for AD7876

GENERAL DESCRIPTION

The AD7870/AD7875/AD7876 is a fast, complete, 12-bit A/D

converter. It consists of a track/hold amplifier, 8 µs successive-

approximation ADC, 3 V buried Zener reference and versatile

interface logic. The ADC features a self-contained internal

clock which is laser trimmed to guarantee accurate control of

conversion time. No external clock timing components are re-

quired; the on-chip clock may he overridden by an external

clock if required.

The parts offer a choice of three data output formats: a single,

parallel, 12-bit word; two 8-bit bytes or serial data. Fast bus ac-

cess times and standard control inputs ensure easy interfacing to

modern microprocessors and digital signal processors.

All parts operate from ±5 V power supplies. The AD7870 and

AD7876 accept input signal ranges of ±3 V and ±10 V, respec-

tively, while the AD7875 accepts a unipolar 0 V to +5 V input

range. The parts can convert full power signals up to 50 kHz.

The AD7870/AD7875/AD7876 feature dc accuracy specifica-

tions such as linearity, full-scale and offset error. In addition,

the AD7870 and AD7875 are fully specified for dynamic perfor-

mance parameters including distortion and signal-to-noise ratio.

The parts are available in a 24-pin, 0.3 inch-wide, plastic or her-

metic dual-in-line package (DIP). The AD7870 and AD7875

are available in a 28-pin plastic leaded chip carrier (PLCC),

while the AD7876 is available and in a 24-pin small outline

(SOIC) package.

PRODUCT HIGHLIGHTS

1. Complete 12-Bit ADC on a Chip.

The AD7870/AD7875/AD7876 provides all the functions

necessary for analog-to-digital conversion and combines a

12-bit ADC with internal clock, track/hold amplifier and

reference on a single chip.

2. Dynamic Specifications for DSP Users.

The AD7870 and AD7875 are fully specified and tested for

ac parameters, including signal-to-noise ratio, harmonic dis-

tortion and intermodulation distortion.

3. Fast Microprocessor Interface.

Data access times of 57 ns make the parts compatible with

modern 8- and 16-bit microprocessors and digital signal pro-

cessors. Key digital timing parameters are tested and guaran-

teed over the full operating temperature range.

FUNCTIONAL BLOCK DIAGRAM

MOS

Complete, 12-Bit, 100 kHz, Sampling ADCs

REV. B

Information furnished by Analog Devices is believed to be accurate and

reliable. However, no responsibility is assumed by Analog Devices for its

use, nor for any infringements of patents or other rights of third parties

which may result from its use. No license is granted by implication or

otherwise under any patent or patent rights of Analog Devices.

One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.

Tel: 617/329-4700 World Wide Web Site: http://www.analog.com

Fax: 617/326-8703 © Analog Devices, Inc., 1997

AD7870

Parameter J, A

K, B

L, C

Units Test Conditions/Comments

DYNAMIC PERFORMANCE

Signal to Noise Ratio

(SNR)

@ +25°C 70 70 72 69 69 dB min V

= 10 kHz Sine Wave, f

SAMPLE

= 100 kHz

MIN

to T

MAX

70 70 71 69 69 dB min Typically 71.5 dB for 0 < V

< 50 kHz

Total Harmonic Distortion (THD) –80 –80 –80 –78 –78 dB max V

= 10 kHz Sine Wave, f

SAMPLE

= 100 kHz

Typically –86 dB for 0 < V

< 50 kHz

Peak Harmonic or Spurious Noise –80 –80 –80 –78 –78 dB max V

= 10 kHz, f

SAMPLE

= 100 kHz

Typically –86 dB for 0 < V

< 50 kHz

Intermodulation Distortion (IMD)

Second Order Terms –80 –80 –80 –78 –78 dB max fa = 9 kHz, fb = 9.5 kHz, f

SAMPLE

= 50 kHz

Third Order Terms –80 –80 –80 –78 –78 dB max fa = 9 kHz, fb = 9.5 kHz, f

SAMPLE

= 50 kHz

Track/Hold Acquisition Time 2 2 2 2 2 µs max

DC ACCURACY

Resolution 12 12 12 12 12 Bits

Minimum Resolution for which

No Missing Codes are Guaranteed 12 12 12 12 12 Bits

Integral Nonlinearity ±1/2 ±1/2 ±1/4 ±1/2 ±1/2 LSB typ

Integral Nonlinearity ±1±1/2 ±1 LSB max

Differential Nonlinearity ±1±1±1 LSB max

Bipolar Zero Error ±5±5±5±5±5 LSB max

Positive Full-Scale Error

±5±5±5±5±5 LSB max

Negative Full-Scale Error

±5±5±5±5±5 LSB max

ANALOG INPUT

Input Voltage Range ±3±3±3±3±3 Volts

Input Current ±500 ±500 ±500 ±500 ±500 µA max

REFERENCE OUTPUT

REF OUT @ +25°C 2.99 2.99 2.99 2.99 2.99 V min

3.01 3.01 3.01 3.01 3.01 V max

REF OUT Tempco ±60 ±60 ±35 ±60 ±35 ppm/°C max

Reference Load Sensitivity (∆REF OUT/∆I) ±1±1±1±1±1 mV max Reference Load Current Change (0–500 µA)

Reference Load Should Not Be Changed

During Conversion.

LOGIC INPUTS

Input High Voltage, V

INH

2.4 2.4 2.4 2.4 2.4 V min V

= 5 V ± 5%

Input Low Voltage, V

INL

0.8 0.8 0.8 0.8 0.8 V max V

= 5 V ± 5%

Input Current, I

±10 ±10 ±10 ±10 ±10 µA max V

= 0 V to V

Input Current (12/8/CLK Input Only) ±10 ±10 ±10 ±10 ±10 µA max V

= V

to V

Input Capacitance, C

IN5

10 10 10 10 10 pF max

LOGIC OUTPUTS

Output High Voltage, V

4.0 4.0 4.0 4.0 4.0 V min I

SOURCE

= 40 µA

Output Low Voltage, V

0.4 0.4 0.4 0.4 0.4 V max I

SINK

= 1.6 mA

DB11–DB0

Floating-State Leakage Current ±10 ±10 ±10 ±10 ±10 µA max

Floating-State Output Capacitance

15 15 15 15 15 pF max

CONVERSION TIME

External Clock (f

CLK

= 2.5 MHz) 8 8 8 8 8 µs max

Internal Clock 7/9 7/9 7/9 7/9 7/9 µs min/µs max

POWER REQUIREMENTS

+5 +5 +5 +5 +5 V nom ±5% for Specified Performance

–5 –5 –5 –5 –5 V nom ±5% for Specified Performance

13 13 13 13 13 mA max Typically 8 mA

6 6 6 6 6 mA max Typically 4 mA

Power Dissipation 95 95 95 95 95 mW max Typically 60 mW

NOTES

Temperature ranges are as follows: J, K, L Versions; 0°C to +70°C: A, B, C Versions; –25°C to +85°C: S, T Versions; –55°C to +125°C.

(pk-pk) = ±3 V.

SNR calculation includes distortion and noise components.

Measured with respect to internal reference and includes bipolar offset error.

Sample tested @ +25°C to ensure compliance.

Specifications subject to change without notice.

AD7870/AD7875/AD7876–SPECIFICATIONS

(VDD = +5 V 6 5%, VSS = –5 V 6 5%,

A6ND = DGND = 0 V, fCLK = 2.5 MHz external, unless otherwise stated. All Specifications Tmin to Tmax unless otherwise noted.)

REV. B

–2–

AD7875/AD7876

Parameter K, B

L, C

Units Test Conditions/Comments

DC ACCURACY

Resolution 12 12 12 Bits

Minimum Resolution for Which

No Missing Codes Are Guaranteed 12 12 12 Bits

Integral Nonlinearity @ +25°C±1±1/2 ±1 LSB max

MIN

to T

MAX

(AD7875 Only) ±1±1±1 LSB max

MIN

to T

MAX

(AD7876 Only) ±1±1/2 ±1 LSB max

Differential Nonlinearity ±1±1±1.5/–1.0 LSB max

Unipolar Offset Error (AD7875 Only) ±5±5±5 LSB max

Bipolar Zero Error (AD7876 Only) ±6±2±6 LSB max

Full-Scale Error at +25°C

±8±8±8 LSB max Typical Full-Scale Error Is ±1 LSB

Full-Scale TC

±60 ±35 ±60 ppm/°C max Typical TC is ±20 ppm/°C

Track/Hold Acquisition Time 2 2 2 µs max

DYNAMIC PERFORMANCE

(AD7875 ONLY)

Signal-to-Noise Ratio

(SNR)

@ +25°C 70 72 69 dB min V

= 10 kHz Sine Wave, f

SAMPLE

= 100 kHz

MIN

to T

MAX

70 71 69 dB min Typically 71.5 dB for 0 < V

< 50 kHz

Total Harmonic Distortion (THD) –80 –80 –78 dB max V

= 10 kHz Sine Wave, f

SAMPLE

= 100 kHz

Typically –86 dB for 0 < V

< 50 kHz

Peak Harmonic or Spurious Noise –80 –80 –78 dB max V

= 10 kHz, f

SAMPLE

= 100 kHz

Typically –86 dB for 0 < V

< 50 kHz

Intermodulation Distortion (IMD)

Second Order Terms –80 –80 –78 dB max fa = 9 kHz, fb = 9.5 kHz, f

SAMPLE

= 50 kHz

Third Order Terms –80 –80 –78 dB max fa = 9 kHz, fb = 9.5 kHz, f

SAMPLE

= 50 kHz

ANALOG INPUT

AD7875 Input Voltage Range 0 to +5 0 to +5 0 to +5 Volts

AD7875 Input Current 500 500 500 µA max

AD7876 Input Voltage Range ±10 ±10 ±10 Volts

AD7876 Input Current ±600 ±600 ±600 µA max

REFERENCE OUTPUT

REF OUT @ +25°C 2.99 2.99 2.99 V min

3.01 3.01 3.01 V max

REF OUT Tempco ±60 ±35 ±60 ppm/°C max Typical Tempco Is ±20 ppm/°C

Reference Load Sensitivity (∆REF OUT/∆I) –1 –1 –1 mV max Reference Load Current Change (0 µA–500 µA)

Reference Load Should Not Be Changed

During Conversion.

LOGIC INPUTS

Input High Voltage, V

INH

2.4 2.4 2.4 V min V

= 5 V ± 5%

Input Low Voltage, V

INL

0.8 0.8 0.8 V max V

= 5 V ± 5%

Input Current, I

±10 ±10 ±10 µA max V

= 0 V to V

Input Current (12/8/CLK Input Only) ±10 ±10 ±10 µA max V

= V

to V

Input Capacitance, C

IN5

10 10 10 pF max

LOGIC OUTPUTS

Output High Voltage, V

4.0 4.0 4.0 V min I

SOURCE

= 40 µA

Output Low Voltage, V

0.4 0.4 0.4 V max I

SINK

= 1.6 mA

DB11–DB0

Floating-State Leakage Current 10 10 10 µA max

Floating-State Output Capacitance

15 15 15 pF max

CONVERSION TIME

External Clock (f

CLK

= 2.5 MHz) 8 8 8 µs max

Internal Clock 7/9 7/9 7/9 µs min/µs max

POWER REQUIREMENTS As per AD7870

NOTES

Temperature ranges are as follows: AD7875: K, L Versions, 0°C to +70°C; B, C Versions, –40°C to +85°C; T Version, –55°C to +125°C. AD7876: B, C Versions,

–40°C to +85°C; T Version, –55 °C to +125°C.

Includes internal reference error and is calculated after unipolar offset error (AD7875) or bipolar zero error (AD7876) has been adjusted out.

Full-scale error refers to both positive and negative full-scale error for the AD7876.

Dynamic performance parameters are not tested on the AD7876 but these are typically the same as for the AD7875.

SNR calculation includes distortion and noise components.

Sample tested @ +25°C to ensure compliance.

Specifications subject to change without notice.

REV. B

AD7870/AD7875/AD7876

–3–

REV. B

AD7870/AD7875/AD7876

–4–

TIMING CHARACTERISTICS

1, 2

Limit at T

MIN

, T

MAX

Limit at T

MIN

, T

MAX

Parameter (J, K, L, A, B, C Versions) (S, T Versions) Units Conditions/Comments

50 50 ns min CONVST Pulse Width

0 0 ns min CS to RD Setup Time (Mode 1)

60 75 ns min RD Pulse Width

0 0 ns min CS to RD Hold Time (Mode 1)

70 70 ns max RD to INT Delay

57 70 ns max Data Access Time after RD

5 5 ns min Bus Relinquish Time after RD

50 50 ns max

0 0 ns min HBEN to RD Setup Time

0 0 ns min HBEN to RD Hold Time

100 100 ns min SSTRB to SCLK Falling Edge Setup Time

115

370 370 ns min SCLK Cycle Time

126

135 150 ns max SCLK to Valid Data Delay. C

= 35 pF

20 20 ns min SCLK Rising Edge to SSTRB

100 100 ns max

10 10 ns min Bus Relinquish Time after SCLK

100 100 ns max

60 60 ns min CS to RD Setup Time (Mode 2)

120 120 ns max CS to BUSY Propagation Delay

200 200 ns min Data Setup Time Prior to BUSY

0 0 ns min CS to RD Hold Time (Mode 2)

0 0 ns min HBEN to CS Setup Time

0 0 ns min HBEN to CS Hold Time

NOTES

Timing specifications in bold print are 100% production tested. All other times are sample tested at +25°C to ensure compliance. All input signals are

specified with tr = tf = 5 ns (10% to 90% of 5 V) and timed from a voltage level of 1.6 V.

Serial timing is measured with a 4.7 k Ω pull-up resistor on SDATA and SSTRB and a 2 k Ω pull-up on SCLK. The capacitance on all three outputs is 35 pF.

is measured with the load circuits of Figure 1 and defined as the time required for an output to cross 0.8 V or 2.4 V.

is defined as the time required for the data lines to change 0.5 V when loaded with the circuits of Figure 2.

SCLK mark/space ratio (measured from a voltage level of 1.6 V) is 40/60 to 60/40.

SDATA will drive higher capacitive loads but this will add to t

since it increases the external RC time constant (4.7 kΩiC

) and hence the time to reach 2.4 V.

Specifications subject to chance without notice.

(VDD = +5 V 6 5%, VSS = –5 V 6 5%, AGND = DGND = 0 V. See Figures 9, 10, 11 and 12.)

ABSOLUTE MAXIMUM RATINGS*

to AGND . . . . . . . . . . . . . . . . . . . . . . . . . .–0.3 V to +7 V

to AGND . . . . . . . . . . . . . . . . . . . . . . . . . .+0.3 V to –7 V

AGND to DGND . . . . . . . . . . . . . . . . . –0.3 V to V

+0.3 V

to AGND . . . . . . . . . . . . . . . . . . . . . . . . . –15 V to +15 V

REF OUT to AGND . . . . . . . . . . . . . . . . . . . . . . . .0 V to V

Digital Inputs to DGND . . . . . . . . . . . . –0.3 V to V

+0.3 V

Digital Outputs to DGND . . . . . . . . . . . –0.3 V to V

+0.3 V

Operating Temperature Range

Commercial (J, K, L Versions – AD7870) . . . 0°C to +70°C

Commercial (K, L Versions – AD7875) . . . . . 0°C to +70°C

Industrial (A, B, C Versions – AD7870) . . . .–25°C to +85°C

Industrial (B, C Versions – AD7875/AD7876)

. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .–40°C to +85°C

Extended (S, T Versions) . . . . . . . . . . . . . .–55°C to +125°C

Storage Temperature Range . . . . . . . . . . . . .–65°C to +150°C

Lead Temperature (Soldering, 10 sec) . . . . . . . . . . . . . +300°C

Power Dissipation (Any Package) to +75°C . . . . . . . . .450 mW

Derates above +75°C by . . . . . . . . . . . . . . . . . . . . . 10 mW/°C

*Stresses above those listed under “Absolute Maximum Ratings” may cause

permanent damage to the device. This is a stress rating only; functional

operation of the device at these or any other conditions above those listed in

the operational sections of this specification is not implied. Exposure

to absolute maximum rating conditions for extended periods may affect

device reliability.

a. High-Z to V

b. High-Z to V

Figure 1. Load Circuits for Access Time

a. V

to High-Z b. V

to High-Z

Figure 2. Load Circuits for Output Float Delay

CAUTION

ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily

accumulate on the human body and test equipment and can discharge without detection. Although

the AD7870/AD7875/AD7876 feature proprietary ESD protection circuitry, permanent damage

may occur on devices subjected to high energy electrostatic discharges. Therefore, proper ESD

precautions are recommended to avoid performance degradation or loss of functionality.

WARNING!

ESD SENSITIVE DEVICE

REV. B

AD7870/AD7875/AD7876

–5–

AD7870 ORDERING GUIDE

Integral

Temperature V

Voltage SNR Nonlinearity Package

Model

1, 2

Range Range (V) (dBs) (LSB) Option

AD7870JN 0°C to +70°C±3 70 min ±1/2 typ N-24

AD7870KN 0°C to +70°C±3 70 min ±1 max N-24

AD7870LN 0°C to +70°C±3 72 min ±1/2 max N-24

AD7870JP 0°C to +70°C±3 70 min ±1/2 typ P-28A

AD7870KP 0°C to +70°C±3 70 min ±1 max P-28A

AD7870LP 0°C to +70°C±3 72 min ±1/2 max P-28A

AD7870AQ –25°C to +85°C±3 70 min ±1/2 typ Q-24

AD7870BQ –25°C to +85°C±3 70 min ±1 max Q-24

AD7870CQ –25°C to +85°C±3 72 min ±1/2 max Q-24

AD7870SQ

–55°C to +125°C±3 70 min ±1/2 typ Q-24

AD7870TQ

–55°C to +125°C±3 70 min ±1 max Q-24

NOTES

To order MIL-STD-883, Class B, processed parts, add /883B to part number. Contact local sales office for military data sheet.

Contact local sales office for LCCC (Leadless Ceramic Chip Carrier) availability.

N = Narrow Plastic DIP; P = Plastic Leaded Chip Carrier (PLCC); Q = Cerdip.

Available to /883B processing only.

AD7875 ORDERING GUIDE

Integral

Temperature V

Voltage SNR Nonlinearity Package

Model

1, 2

Range Range (V) (dBs) (LSB) Option

AD7875KN 0°C to +70°C 0 to +5 70 min ±1 max N-24

AD7875LN 0°C to +70°C 0 to +5 72 min ±1/2 max N-24

AD7875KP 0°C to +70°C 0 to +5 70 min ±1 max P-28A

AD7875LP 0°C to +70°C 0 to +5 72 min ±1/2 max P-28A

AD7875BQ –40°C to +85°C 0 to +5 70 min ±1 max Q-24

AD7875CQ –40°C to +85°C 0 to +5 72 min ±1/2 max Q-24

AD7875TQ

–55°C to +125°C 0 to +5 70 min ±1 max Q-24

NOTES

To order MIL-STD-883, Class B. processed parts, add /883B to part number. Contact local sales office for military data sheet.

Contact local sales office for LCCC (Leadless Ceramic Chip Carrier) availability.

N = Narrow Plastic DlP; P = Plastic Leaded Chip Carrier (PLCC); Q = Cerdip.

Available to /883B processing only.

AD7876 ORDERING GUIDE

Integral

Temperature V

Voltage Nonlinearity Package

Model

Range Range (V) (LSB) Option

AD7876BN –40°C to +85°C±10 ±1 max N-24

AD7876CN –40°C to +85°C±10 ±1/2 max N-24

AD7876BR –40°C to +85°C±10 ±1 max R-24

AD7876CR –40°C to +85°C±10 ±1/2 max R-24

AD7876BQ –40°C to +85°C±10 ±1 max Q-24

AD7876CQ –40°C to +85°C±10 ±1/2 max Q-24

AD7876TQ

–55°C to +125°C±10 ±1 max Q-24

NOTES

To order MIL-STD-883, Class B, processed parts, add /883B to the part number. Contact local sales office for military data sheet.

N = Narrow Plastic DIP; Q = Cerdip; R = Small Outline IC (SOIC).

Available to /883B processing only.

REV. B

AD7870/AD7875/AD7876

–6–

PIN FUNCTION DESCRIPTION

DIP Pin

Pin No. Mnemonic Function

1RD Read. Active low logic input. This input is used in conjunction with CS low to enable the data outputs.

2BUSY/INT Busy/Interrupt, Active low logic output indicating converter status. See timing diagrams.

3 CLK Clock input. An external TTL-compatible clock may be applied to this input pin. Alternatively, tying this pin to

enables the internal laser-trimmed clock oscillator.

4 DB11/HBEN Data Bit 11 (MSB)/High Byte Enable. The function of this pin is dependent on the state of the 12/8/CLK input (see

below). When 12-bit parallel data is selected, this pin provides the DB11 output. When byte data is selected, this pin

becomes the HBEN logic input HBEN is used for 8-bit bus interfacing. When HBEN is low, DB7/LOW to DB0/DB8

become DB7 to DB0. With HBEN high, DB7/LOW to DB0/DB8 are used for the upper byte of data (see Table I).

5 DB10/SSTRB Data Bit 10/Serial Strobe. When 12-bit parallel data is selected, this pin provides the DB10 output. SSTRB is an

active low open-drain output that provides a strobe or framing pulse for serial data. An external 4.7 kΩ pull-up

resistor is required on SSTRB.

6 DB9/SCLK Data Bit 9/Serial Clock. When 12-bit parallel data is selected, this pin provides the DB9 output. SCLK is the gated

serial clock output derived from the internal or external ADC clock. If the 12/8/CLK input is at –5 V, then SCLK

runs continuously. If 12/8/CLK is at 0 V, then SCLK is gated off after serial transmission is complete. SCLK is an

open-drain output and requires an external 2 kΩ pull-up resistor.

7 DB8/SDATA Data Bit 8/Serial Data. When 12-bit parallel data is selected, this pin provides the DB8 output. SDATA is an open-

drain serial data output which is used with SCLK and SSTRB for serial data transfer. Serial data is valid on the fall-

ing edge of SCLK while SSTRB is low. An external 4.7 kΩ pull-up resistor is required on SDATA.

8–11 DB7/LOW– Three-state data outputs controlled by CS and RD. Their function depends on the 12/8/CLK and HBEN inputs.

DB4/LOW With 12/8/CLK high, they are always DB7–DB4. With 12/8/CLK low or –5 V, their function is controlled by HBEN

(see Table I).

12 DGND Digital Ground. Ground reference for digital circuitry.

13–16 DB3/DB11– Three-state data outputs which are controlled by CS and RD. Their function depends on the 12/8/CLK and HBEN

DB0/DB8 inputs. With 12/8/CLK high, they are always DB3–DB0. With 12/8/CLK low or –5 V, their function is controlled by

HBEN (see Table I).

Table I. Output Data for Byte Interfacing

HBEN DB7/LOW DB6/LOW DB5/LOW DB4/LOW DB3/DB11 DB2/DB10 DB1/DB9 DB0/DB8

HIGH LOW LOW LOW LOW DB11(MSB) DB10 DB9 DB8

LOW DB7 DB6 DB5 DB4 DB3 DB2 DB1 DB0 (LSB)

17 V

Positive Supply, +5 V ± 5%.

18 AGND Analog Ground. Ground reference for track/hold, reference and DAC.

19 REF OUT Voltage Reference Output. The internal 3 V reference is provided at this pin. The external load capability is 500 µA.

20 V

Analog Input. The analog input range is ±3 V for the AD7870, ±10 V for the AD7876 and 0 V to +5 V for the AD7875.

21 V

Negative Supply, –5 V ± 5%.

22 12/8/CLK Three Function Input. Defines the data format and serial clock format. With this pin at +5 V, the output data for-

mat is 12-bit parallel only. With this pin at 0 V, either byte or serial data is available and SCLK is not continuous.

With this pin at –5 V, either byte or serial data is again available but SCLK is now continuous.

23 CONVST Convert Start. A low to high transition on this input puts the track/hold into its hold mode and starts conversion.

This input is asynchronous to the CLK input.

24 CS Chip Select. Active low logic input. The device is selected when this input is active. With CONVST tied low, a new

conversion is initiated when CS goes low.

DIP and SOIC

PLCC

PIN CONFIGURATIONS

1PIN CONFIGURATIONS ARE THE SAME FOR

THE AD7875 AND AD7876.

2THE AD7870 AND AD7875 ARE AVAILABLE IN

DIP AND PLCC; THE AD7870A IS AVAILABLE IN

PLASTIC DIP; THE AD7875 AND AD7876 ARE

AVAILABLE IN SOIC AND DIP.

REV. B

AD7870/AD7875/AD7876

–7–

to the conversion time plus the track/hold amplifier

acquisition time. For a 2.5 MHz input clock the throughput

rate is 10 µs max.

The operation of the track/hold is essentially transparent to the

user. The track/hold amplifier goes from its tracking mode to its

hold mode at the start of conversion. If the CONVST input is

used to start conversion then the track to hold transition occurs

on the rising edge of CONVST. If CS starts conversion, this

transition occurs on the falling edge of CS.

ANALOG INPUT

The three parts differ from each other in the analog input volt-

age range that they can handle. The AD7870 accepts ±3 V

input signals, the AD7876 accepts a ±10 V input range, while

the input range for the AD7875 is 0 V to +5 V.

Figure 5a shows the AD7870 analog input. The analog input

range is ±3 V into an input resistance of typically 15 kΩ. The

designed code transitions occur midway between successive

integer LSB values (i.e., 1/2 LSB, 3/2 LSBs, 5/2 LSBs . . .

FS–3/2 LSBs). The output code is twos complement binary

with 1 LSB = FS/4096 = 6 V/4096 = 1.46 mV. The ideal input/

output transfer function is shown in Figure 6.

Figure 5a. AD7870 Analog Input

The AD7876 analog input structure is shown in Figure 5b. The

analog input range is ±10 V into an input resistance of typically

33 kΩ. As before, the designed code transitions occur midway

between successive integer LSB values. The output code is 2s

complement with 1 LSB = FS/4096 = 20 V/4096 = 4.88 mV.

The ideal input/output transfer function is shown in Figure 6.

Figure 5b. AD7876 Analog Input

Figure 5c shows the analog input for the AD7875. The input

range is 0 V to +5 V into an input resistance of typically 25 kΩ.

Once again, the designed code transitions occur midway

between successive integer LSB values. The output code is

CONVERTER DETAILS

The AD7870/AD7875/AD7876 is a complete 12-bit A/D con-

verter, requiring no external components apart from power

supply decoupling capacitors. It is comprised of a 12-bit suc-

cessive approximation ADC based on a fast settling voltage

output DAC, a high speed comparator and SAR, a track/hold

amplifier, a 3 V buried Zener reference, a clock oscillator and

control logic.

INTERNAL REFERENCE

The AD7870/AD7875/AD7876 has an on-chip temperature

compensated buried Zener reference that is factory trimmed to

3 V ±10 mV. Internally it provides both the DAC reference

and the d c bias required for bipolar operation (AD7870 and

AD7876). The reference output is available (REF OUT) and

capable of providing up to 500 µA to an external load.

The maximum recommended capacitance on REF OUT for

normal operation is 50 pF. If the reference is required for use

external to the ADC, it should be decoupled with a 200 Ω

resistor in series with a parallel combination of a 10 µF tanta-

lum capacitor and a 0.1 µF ceramic capacitor. These decoupling

components are required to remove voltage spikes caused by

the ADC’s internal operation.

Figure 3. Reference Circuit

The reference output voltage is 3 V. For applications using the

AD7875 or AD7876, a 5 V or 10 V reference may be required.

Figure 4 shows how to scale the 3 V REF OUT voltage to pro-

vide either a 5 V or 10 V external reference.

Figure 4. Generating a 5 V or 10 V Reference

TRACK-AND-HOLD AMPLIFIER

The track-and-hold amplifier on the analog input of the AD7870/

AD7875/AD7876 allows the ADC to accurately convert input

frequencies to 12-bit accuracy. The input bandwidth of the

track/hold amplifier is much greater than the Nyquist rate of the

ADC even when the ADC is operated at its maximum through-

put rate. The 0.1 dB cutoff frequency occurs typically at 500

kHz. The track/hold amplifier acquires an input signal to 12-bit

accuracy in less than 2 µs. The overall throughput rate is equal

REV. B

AD7870/AD7875/AD7876

–8–

straight binary with 1 LSB = FS/4096 = 5 V/4096 = 1.22 mV.

The ideal input/output transfer function is shown in Figure 7.

Figure 5c. AD7875 Analog Input

Figure 6. AD7870/AD7876 Transfer Function

Figure 7. AD7875 Transfer Function

OFFSET AND FULL-SCALE ADJUSTMENT—AD7870

In most digital signal processing (DSP) applications, offset and

full-scale errors have little or no effect on system performance.

Offset error can always be eliminated in the analog domain by

ac coupling. Full-scale error effect is linear and does not cause

problems as long as the input signal is within the full dynamic

range of the ADC. Some applications will require that the input

signal span the full analog input dynamic range. In such applica-

tions, offset and full-scale error will have to be adjusted to zero.

Where adjustment is required, offset error must be adjusted be-

fore full-scale error. This is achieved by trimming the offset of

the op amp driving the analog input of the AD7870 while the

input voltage is 1/2 LSB below ground. The trim procedure is as

follows: apply a voltage of –0.73 mV(–1/2 LSB) at V

in Figure

8 and adjust the op amp offset voltage until the ADC output

code flickers between 1111 1111 1111 and 0000 0000 0000.

Gain error can be adjusted at either the first code transition

(ADC negative full-scale) or the last code transition (ADC posi-

tive full scale). The trim procedures for both cases are as follows

(see Figure 8).

Figure 8. Offset and Full-Scale Adjust Circuit

Positive Full-Scale Adjust

Apply a voltage of 2.9978 V (FS/2 – 3/2 LSBs) at V

. Adjust R2

until the ADC output code flickers between 0111 1111 1110

and 0111 1111 1111.

Negative Full-Scale Adjust

Apply a voltage of –2.9993 V (–FS/2 + 1/2 LSB) at V

and ad-

just R2 until the ADC output code flickers between 1000 0000

0000 and 1000 0000 0001.

OFFSET AND FULL-SCALE ADJUSTMENT—AD7876

The offset and full-scale adjustment for the AD7876 is similar

to that just outlined for the AD7870. The trim procedure, for

those applications that do require adjustment, is as follows:

apply a voltage of –2.44 mV (–1/2 LSB) at V

and adjust the op

amp offset voltage until the ADC output code flickers between

1111 1111 1111 and 0000 0000 0000. Full-scale error can be

adjusted at either the first code transition (ADC negative full

scale) or the last code transition (ADC positive full scale). The

trim procedure for both case is as follows (see Figure 8):

Positive Full-Scale Adjust

Apply a voltage of 9.9927 V (FS/2 –3/2 LSBs) at V

. Adjust R2

until the ADC output code flickers between 0111 1111 1110

and 0111 1111 1111.

Negative Full-Scale Adjust

Apply a voltage of –9.9976 V (FS/2 + 1/2 LSB) at V

and adjust

R2 until the ADC output code flickers between 1000 0000 0000

and 1000 0000 0001.

REV. B

AD7870/AD7875/AD7876

–9–

functions. Serial data is available during conversion with a word

length of 16 bits; four leading zeros, followed by the 12-bit con-

version result starting with the MSB. The data is synchronized

to the serial clock output (SCLK) and framed by the serial

strobe (SSTRB). Data is clocked out on a low to high transition

of the serial clock and is valid on the falling edge of this clock

while the SSTRB output is low. SSTRB goes low within three

clock cycles after CONVST, and the first serial data bit (the first

leading zero) is valid on the first falling edge of SCLK. All three

serial lines are open-drain outputs and require external pull-up

resistors.

The serial clock out is derived from the ADC clock source,

which may be internal or external. Normally, SCLK is required

during the serial transmission only. In these cases, it can be shut

down at the end of conversion to allow multiple ADCs to share

a common serial bus. However, some serial systems (e.g.,

TMS32020) require a serial clock that runs continuously. Both

options are available on the AD7870/AD7875/AD7876 using

the 12/8/CLK input. With this input at –5 V, the serial clock

(SCLK) runs continuously; when 12/8/CLK is at 0 V, SCLK is

turned off at the end of transmission.

MODE 1 INTERFACE

Conversion is initiated by a low going pulse on the CONVST

input. The rising edge of this CONVST pulse starts conversion

and drives the track/hold amplifier into its hold mode. Conver-

sion will not be initiated if the CS is low. The BUSY/INT status

output assumes its INT function in this mode. INT is normally

high and goes low at the end of conversion. This INT line can

be used to interrupt the microprocessor. A read operation to the

ADC accesses the data and the INT line is reset high on the fall-

ing edge of CS and RD. The CONVST input must be high

when CS and RD are brought low for the ADC to operate cor-

rectly in this mode. The CS or RD input should not be hard-

wired low in this mode. Data cannot be read from the part

during conversion because the on-chip latches are disabled

when conversion is in progress. In applications where precise

sampling is not critical, the CONVST pulse can be generated

from a microprocessor WR line OR-gated with a decoded ad-

dress. In some applications, depending on power supply turn-on

time, the AD7870/AD7875/AD7876 may perform a conversion

on power-up. In this case, the INT line will power-up low and a

dummy read to the AD7870/AD7875/AD7876 will be required

to reset the INT line before starting conversion.

Figure 9 shows the Mode 1 timing diagram for a 12-bit parallel

data output format (12/8/CLK = +5 V). A read to the ADC at

the end of conversion accesses all 12 bits of data at the same

time. Serial data is not available for this data output format.

Figure 9. Mode 1 Timing Diagram, 12-Bit Parallel Read

OFFSET AND FULL-SCALE ADJUSTMENT—AD7875

Similar to the AD7870, most of the DSP applications in which

the AD7875 will be used will not require offset and full-scale

adjustment. For applications that do require adjustment, offset

error must be adjusted before full-scale (gain) error. This is

achieved by applying an input voltage of 0.61 mV (1/2 LSB) to

in Figure 8 and adjusting the op amp offset voltage until the

ADC output code flickers between 0000 0000 0000 and 0000

0000 0001. For full-scale adjustment, apply an input voltage of

4.9982 V (FS – 3/2 LSBs) to V

and adjust R2 until the ADC

output code flickers between 1111 1111 1110 and 1111 1111

1111.

TIMING AND CONTROL

The AD7870/AD7875/AD7876 is capable of two basic operating

modes. In the first mode (Mode 1), the CONVST line is used to

start conversion and drive the track/hold into its hold mode. At

the end of conversion the track/hold returns to its tracking mode.

It is intended principally for digital signal processing and other

applications where precise sampling in time is required. In these

applications, it is important that the signal sampling occurs at ex-

actly equal intervals to minimize errors due to sampling uncer-

tainty or jitter. For these cases, the CONVST line is driven by a

timer or some precise clock source.

The second mode is achieved by hard-wiring the CONVST line

low. This mode (Mode 2) is intended for use in systems where

the microprocessor has total control of the ADC, both initiating

the conversion and reading the data. CS starts conversion and

the microprocessor will normally be driven into a WAIT state

for the duration of conversion by BUSY/INT.

DATA OUTPUT FORMATS

In addition to the two operating modes, the AD7870/AD7875/

AD7876 also offers a choice of three data output formats, one

serial and two parallel. The parallel data formats are a single,

12-bit parallel word for 16-bit data buses and a two-byte format

for 8-bit data buses. The data format is controlled by the 12/8/

CLK input. A logic high on this pin selects the 12-bit parallel

output format only. A logic low or –5 V applied to this pin al-

lows the user access to either serial or byte formatted data.

Three of the pins previously assigned to the four MSBs in paral-

lel form are now used for serial communications while the

fourth pin becomes a control input for the byte-formatted data.

The three possible data output formats can be selected in either

of the modes of operation.

Parallel Output Format

The two parallel formats available on the part are a 12-bit wide

data word and a two-byte data word. In the first, all 12 bits of

data are available at the same time on DB11 (MSB) through

DB0 (LSB). In the second, two reads are required to access the

data. When this data format is selected, the DB11/HBEN pin

assumes the HBEN function. HBEN selects which byte of data

is to be read from the ADC. When HBEN is low, the lower

eight bits of data are placed on the data bus during a read op-

eration; with HBEN high, the upper four bits of the 12-bit word

are placed on the data bus. These four bits are right justified

and thereby occupy the lower nibble of data while the upper

nibble contains four zeros.

Serial Output Format

Serial data is available on the AD7870/AD7875/AD7876 when

the 12/8/CLK input is at 0 V or –5 V and in this case the DB10/

SSTRB, DB9/SCLK and DB8/SDATA pins assume their serial

REV. B

AD7870/AD7875/AD7876

–10–

Figure 10. Mode 1 Timing Diagram, Byte or Serial Read

its BUSY function. BUSY goes low at the start of conversion,

stays low during the conversion and returns high when the con-

version is complete. It is normally used in parallel interfaces to

drive the microprocessor into a WAIT state for the duration of

conversion.

Figure 11 shows the Mode 2 timing diagram for the 12-bit par-

allel data output format (12/8/CLK = +5 V). In this case, the

ADC behaves like slow memory. The major advantage of this

interface is that it allows the microprocessor to start conversion,

WAIT and then read data with a single READ instruction. The

user does not have to worry about servicing interrupts or ensur-

ing that software delays are long enough to avoid reading during

conversion.

Figure 11. Mode 2 Timing Diagram, 12-Bit Parallel Read

The Mode 1 timing diagram for byte and serial data is shown in

Figure 10. INT goes low at the end of conversion and is reset

high by the first falling edge of CS and RD. This first read at the

end of conversion can either access the low byte or high byte of

data depending on the status of HBEN (Figure 10 shows low

byte only for example). The diagram shows both a noncontinu-

ously and a continuously running clock (dashed line).

MODE 2 INTERFACE

The second interface mode is achieved by hard wiring CONVST

low and conversion is initiated by taking CS low while HBEN is

low. The track/hold amplifier goes into the hold mode on the

falling edge of CS. In this mode, the BUSY/INT pin assumes

REV. B

AD7870/AD7875/AD7876

–11–

Figure 12. Mode 2 Timing Diagram, Byte or Serial Read

The Mode 2 timing diagram for byte and serial data is shown in

Figure 12. For two-byte data read, the lower byte (DB0–DB7)

has to be accessed first since HBEN must be low to start con-

version. The ADC behaves like slow memory for this first read,

but the second read to access the upper byte of data is a normal

read. Operation of the serial functions is identical between

Mode 1 and Mode 2. The timing diagram of Figure 12 shows

both a noncontinuously and a continuously running SCLK

(dashed line).

DYNAMIC SPECIFICATIONS

The AD7870 and AD7875 are specified and 100% tested for

dynamic performance specifications as well as traditional dc

specifications such as integral and differential nonlinearity. Al-

though the AD7876 is not production tested for ac parameters,

its dynamic performance is similar to the AD7870 and AD7875.

The ac specifications are required for signal processing applica-

tions such as speech recognition, spectrum analysis and high

speed modems. These applications require information on the

ADC’s effect on the spectral content of the input signal. Hence,

the parameters for which the AD7870 and AD7875 are speci-

fied include SNR, harmonic distortion, intermodulation distor-

tion and peak harmonics. These terms are discussed in more

detail in the following sections.

Signal-to-Noise Ratio (SNR)

SNR is the measured signal-to-noise ratio at the output of the

ADC. The signal is the rms magnitude of the fundamental.

Noise is the rms sum of all the nonfundamental signals up to

half the sampling frequency (FS/2) excluding dc. SNR is depen-

dent upon the number of quantization levels used in the digiti-

zation process; the more levels, the smaller the quantization

noise. The theoretical signal-to-noise ratio for a sine wave input

is given by

SNR = (6.02N + 1.76) dB (1)

where N is the number of bits. Thus for an ideal 12-bit con-

verter, SNR = 74 dB.

sine-wave signal of very low distortion to the V

input which is

sampled at a 100 kHz sampling rate. A Fast Fourier Transform

(FFT) plot is generated from which the SNR data can be ob-

tained. Figure 13 shows a typical 2048 point FFT plot of the

AD7870KN/AD7875KN with an input signal of 25 kHz and a

sampling frequency of 100 kHz. The SNR obtained from this

graph is 72.6 dB. It should be noted that the harmonics are

taken into account when calculating the SNR.

Figure 13. FFT Plot

Effective Number of Bits

The formula given in (1) relates SNR to the number of bits.

Rewriting the formula, as in (2), it is possible to get a measure

of performance expressed in effective number of bits (N).

N = (2)

The effective number of bits for a device can be calculated di-

rectly from its measured SNR.

SNR – 1.76

6.02

REV. B

AD7870/AD7875/AD7876

–12–

Figure 15. IMD Plot

AC Linearity Plot

When a sine wave of specified frequency is applied to the V

input of the AD7870/AD7875 and several million samples are

taken, a histogram showing the frequency of occurrence of each

of the 4096 ADC codes can be generated. From this histogram

data it is possible to generate an ac integral linearity plot as

shown in Figure 16. This shows very good integral linearity per-

formance from the AD7870/AD7875 at an input frequency of

25 kHz. The absence of large spikes in the plot shows good dif-

ferential linearity. Simplified versions of the formulae used are

outlined below.

INL(i) =

V(i)–V(o)

V(fs)–V(o) ⋅ 4096











–i

where INL(i) is the integral linearity at code i. V(fs) and V(o)

are the estimated full-scale and offset transitions and V(i) is the

estimated transition for the i

code.

V(i) the estimated code transition point is derived as follows:

V(i) = –A • Cos

π⋅cum(i)

[]

where A is the peak signal amplitude,

N is the number of histogram samples

and cum(i) = Σ

in=0

V(n) occurrences

Figure 16. AC INL Plot

Figure 14 shows a typical plot of effective number of bits versus

frequency for an AD7870KN/AD7875KN with a sampling fre-

quency of 100 kHz. The effective number of bits typically falls

between 11.7 and 11.85 corresponding to SNR figures of 72.2

and 73.1 dB.

Figure 14. Effective Number of Bits vs. Frequency

Total Harmonic Distortion (THD)

THD is the ratio of the rms sum of harmonics to the rms value

of the fundamental. For the AD7870/AD7875, THD is defined

THD = 20 log

where V

is the rms amplitude of the fundamental and V

, V

and V

are the rms amplitudes of the second through the

sixth harmonic. The THD is also derived from the FFT plot of

the ADC output spectrum.

Intermodulation Distortion

With inputs consisting of sine waves at two frequencies, fa and

fb, any active device with nonlinearities will create distortion

products at sum and difference frequencies of mfa ± nfb where

m, n = 0, 1, 2, 3, etc. Intermodulation terms are those for which

neither m nor n are equal to zero. For example, the second or-

der terms include (fa + fb) and (fa – fb), while the third order

terms include (2fa + fb), (2fa – fb), (fa + 2fb) and (fa – 2fb).

Using the CCIF standard, where two input frequencies near the

top end of the input bandwidth are used, the second and third

order terms are of different significance. The second order terms

are usually distanced in frequency from the original sine waves

while the third order terms are usually at a frequency close to

the input frequencies. As a result, the second and third order

terms are specified separately. The calculation of the intermodu-

lation distortion is as per the THD specification where it is the

ratio of the rms sum of the individual distortion products to the

rms amplitude of the fundamental expressed in dBs. In this

case, the input consists of two, equal amplitude, low distortion

sine waves. Figure 15 shows a typical IMD plot for the AD7870/

AD7875.

Peak Harmonic or Spurious Noise

Peak harmonic or spurious noise is defined as the ratio of the

rms value of the next largest component in the ADC output

spectrum (up to FS/2 and excluding dc) to the rms value of the

fundamental. Normally, the value of this specification will be

determined by the largest harmonic in the spectrum, but for

parts where the harmonics are buried in the noise floor the peak

will be a noise peak.

REV. B

AD7870/AD7875/AD7876

–13–

MICROPROCESSOR INTERFACE

The AD7870/AD7875/AD7876 has a wide variety of interfacing

options. It offers two operating modes and three data-output for-

mats. Fast data access times allow direct interfacing to most mi-

croprocessors including the DSP processors.

Parallel Read Interfacing

Figures 17 to 19 show interfaces to the ADSP-2100, TMS32010

and the TMS32020 DSP processors. The ADC is operating in

Mode 1, parallel read for all three interfaces. An external timer

controls conversion start asynchronously to the microprocessor.

At the end of each conversion the ADC BUSY/INT interrupts

the microprocessor. The conversion result is read from the ADC

with the following instruction:

ADSP-2100: MR0 = DM(ADC)

TMS32010: IN D,ADC

TMS32020: IN D,ADC

MR0 = ADSP-2100 MR0 Register

D = Data Memory Address

ADC = AD7870/AD7875/AD7876 Address

Some applications may require that conversions be initiated by

the microprocessor rather than an external timer. One option is

to decode the CONVST signal from the address bus so that a

write operation to the ADC starts a conversion. Data is read at

the end of conversion as described earlier. Note: a read operation

must not be attempted during conversion.

Figure 17. ADSP-2100 Parallel Interface

Figure 18. TMS32010 Parallel Interface

Figure 19. TMS32020 Parallel Interface

Two Byte Read Interfacing

68008 Interface

Figure 20 shows an 8-bit bus interface for the MC68008 micro-

processor. For this interface, the 12/8/CLK input is tied to 0 V

and the DB11/HBEN pin is driven from the microprocessor

least significant address bit. Conversion start control is provided

by the microprocessor. In this interface example, a Move in-

struction from the ADC address both starts a conversion and

reads the conversion result.

MOVEW ADC,DO

ADC = AD7870/AD7875/AD7876 address

D0 = 68008 D0 register

This is a two byte read instruction. During the first read opera-

tion BUSY, in conjunction with CS, forces the microprocessor

to WAIT for the ADC conversion. At the end of conversion the

ADC low byte (DB7–DB0) is loaded into D15–D8 of the D0

D7–D0 of the D0 register. The following Rotate instruction to

the D0 register swaps the high and low bytes to the correct

format.

R0L = 8, D0.

Note: while executing the two byte read instruction above,

WAIT states are inserted during the first read operation only

and not for the second.

Figure 20. MC68008 Byte Interface

REV. B

AD7870/AD7875/AD7876

–14–

Serial Interfacing

Figures 21 to 24 show the AD7870/AD7875/AD7876 config-

ured for serial interfacing. In all four interfaces, the ADC is con-

figured for Mode 1 operation. The interfaces show a timer

driving the CONVST input, but this could be generated from a

decoded address if required. The SCLK, SDAT and SSTRB are

open-drain outputs. If these are required to drive capacitive

loads in excess 35 pF, buffering is recommended.

DSP56000 Serial Interface

Figure 21 shows a serial interface between the AD7870/

AD7875/AD7876 and the DSP56000. The interface arrange-

ment is two-wire with the ADC configured for noncontinuous

clock operation (12/8/CLK = 0 V). The DSP56000 is config-

ured for normal mode asynchronous operation with gated clock.

It is also set up for a 16-bit word with SCK and SC1 as inputs

and the FSL control bit set to a 0. In this configuration, the

DSP56000 assumes valid data on the first falling edge of SCK.

Since the ADC provides valid data on this first edge, there is no

need for a strobe or framing pulse for the data. SCLK and

SDATA are gated off when the ADC is not performing a con-

version. During conversion, data is valid on the SDATA output

of the ADC and is clocked into the receive data shift register of

the DSP56000. When this register has received 16 bits of data,

it generates an internal interrupt on the DSP56000 to read the

data from the register.

Figure 21. DSP56000 Serial Interface

The DSP56000 and AD7870/AD7875/AD7876 can also be

configured for continuous clock operation (12/8/CLK = –5 V).

In this case, a strobe pulse is required by the DSP56000 to indi-

cate when data is valid. The SSTRB output of the ADC is in-

verted and applied to the SC1 input of the DSP56000 to

provide this strobe pulse. All other conditions and connections

are the same as for gated clock operation.

NEC7720/77230 Serial Interface

A serial interface between the AD7870/AD7875/AD7876 and

the NEC7720 is shown in Figure 22. In the interface shown, the

ADC is configured for continuous clock operation. This can be

changed to a noncontinuous clock by simply tying the 12/8/CLK

input of the ADC to 0 V with all other connections remaining

the same. The NEC7720 expects valid data on the rising edge of

its SCK input and therefore an inverter is required on the

SCLK output of the ADC. The NEC7720 is configured for a

16-bit data word. Once the 16 bits of data have been received

by the SI register of the NEC7720, an internal interrupt is gen-

erated to read the contents of the SI register.

The NEC77230 interface is similar to that just outlined for the

NEC7720. However, the clock input of the NEC77230 is

SICLK. Additionally, no inverter is required between the ADC

SCLK output and this SICLK input since the NEC77230 as-

sumes data is valid on the falling edge of SICLK.

Figure 22. NEC7720 Serial Interface

TMS32020 Serial Interface

Figure 23 shows a serial interface between the AD7870/ AD7875/

AD7876 and the TMS32020. The AD7870/AD7875/AD7876 is

configured for continuous clock operation. Note, the ADC will

not interface correctly to the TMS32020 if the ADC is config-

ured for a noncontinuous clock. Data is clocked into the data

receive register (DRR) of the TMS32020 during conversion. As

with the previous interfaces, when a 16-bit word is received by

the TMS32020 it generates an internal interrupt to read the

data from the DRR.

Figure 23. TMS32020 Serial Interface

ADSP-2101/ADSP-2102 Serial Interface

Figure 24 shows a serial interface between the AD7870/AD7875/

AD7876 and the ADSP-2101/ADSP-2102. The ADC is config-

ured for continuous clock operation. Data is clocked into the

serial port register of the ADSP-2101/ADSP-2102 during con-

version. As with the previous interfaces, when a 16-bit data

word is received by the ADSP-2101/ADSP-2102 an internal mi-

croprocessor interrupt is generated and the data is read from the

serial port register.

Figure 24. ADSP-2101/ADSP-2102 Serial Interface

REV. B

AD7870/AD7875/AD7876

–15–

STAND-ALONE OPERATION

The AD7870/AD7875/AD7876 can be used in its Mode 2, par-

allel interface mode for stand-alone operation. In this case, con-

version is initiated with a pulse to the ADC CS input. This

pulse must be longer than the conversion time of the ADC. The

BUSY output is used to drive the RD input. Data is latched

from the ADC DB0–DB11 outputs to an external latch on the

rising edge of BUSY.

Figure 25. Stand-Alone Operation

APPLICATION HINTS

Good printed circuit board (PCB) layout is as important as the

overall circuit design itself in achieving high speed A/D perfor-

mance. The designer has to be conscious of noise both in the

ADC itself and in the preceding analog circuitry. Switching

mode power supplies are not recommended as the switching

spikes will feed through to the comparator causing noisy code

transitions. Other causes of concern are ground loops and digi-

tal feedthrough from microprocessors. These are factors which

influence any ADC, and a proper PCB layout which minimizes

these effects is essential for best performance.

LAYOUT HINTS

Ensure that the layout for the printed circuit board has the digi-

tal and analog signal lines separated as much as possible. Take

care not to run any digital track alongside an analog signal track.

Guard (screen) the analog input with AGND.

Establish a single point analog ground (star ground) separate

from the logic system ground at the AGND pin or as close as

possible to the ADC. Connect all other grounds and the

AD7870/AD7875/AD7876 DGND to this single analog ground

point. Do not connect any other digital grounds to this analog

ground point.

Low impedance analog and digital power supply common re-

turns are essential to low noise operation of the ADC, so make

the foil width for these tracks as wide as possible. The use of

ground planes minimizes impedance paths and also guards the

analog circuitry from digital noise. The circuit layout of Figures

30 and 31 have both analog and digital ground planes which are

kept separated and only joined together at the AD7870/

AD7875/AD7876 AGND pin.

NOISE

Keep the input signal leads to V

and signal return leads from

AGND as short as possible to minimize input noise coupling. In

applications where this is not possible, use a shielded cable be-

tween the source and the ADC. Reduce the ground circuit im-

pedance as much as possible since any potential difference in

grounds between the signal source and the ADC appears as an

error voltage in series with the input signal.

DATA ACQUISITION BOARD

Figure 28 shows the AD7870/AD7875/AD7876 in a data acqui-

sition circuit. The corresponding printed circuit board (PCB)

layout and silkscreen are shown in Figures 29 to 31. The board

layout has three interface ports: one serial and two parallel. One

of the parallel ports is directly compatible with the ADSP-2100

evaluation board expansion connector.

The only additional component required for a full data acquisi-

tion system is an antialiasing filter. A component grid is pro-

vided near the analog input on the PCB, which may be used for

such a filter or any other input conditioning circuitry. To facili-

tate this option there is a shorting plug (labelled LK1 on the

PCB) on the analog input track. If this shorting plug is used, the

analog input connects to the buffer amplifier driving the ADC;

if this shorting plug is omitted, a wire link can be used to con-

nect the analog input to the PCB component grid.

INTERFACE CONNECTIONS

There are two parallel connectors labeled SKT4 and SKT6 and

one serial connector labeled SKT5. A shorting plug option

(LK3 in Figure 28) on the ADC 12/8/CLK input configures

the ADC for the appropriate interface (see Pin Function

Description).

SKT6 is a 96-contact (3-ROW) Eurocard connector that is

directly compatible with the ADSP-2100 Evaluation Board

Prototype Expansion Connector. The expansion connector on

the ADSP-2100 has eight decoded chip enable outputs labeled

ECE1 to ECE8. ECE6 is used to drive the ADC CS input on

the data acquisition board. To avoid selecting on board RAM

sockets at the same time, LK6 on the ADSP-2100 board must

be removed. In addition, the ADSP-2100 expansion connector

has four interrupts labelled EIRQ0 to EIRQ3. The ADC BUSY/

INT output connects to EIRQ0. There is a single wait state gen-

erator connected to EDMACK to allow the ADC to interface to

the faster versions of the ADSP-2100.

SKT4 is a 26-way (2-ROW) IDC connector. This connector

contains all the signal contacts as SKT6 with the exception of

EDMACK which is connected to SKT6 only. It also contains

decoded R/W and STRB inputs which are necessary for

TMS32020 interfacing. The SKT4 pinout is shown in Fig-

ure 26.

Figure 26. SKT4, IDC Connector Pinout

REV. B

AD7870/AD7875/AD7876

–16–

SKT5 is a 9-way D-type connector that is meant for serial inter-

facing only. An inverted DB9/SCLK output is also provided on

this connector for systems that accept data on a rising clock

edge. The SKT5 pinout is shown in Figure 27.

Figure 27. SKT5, D-Type Connector Pinout

SKT1, SKT2 and SKT3 are three BNC connectors which pro-

vide input connections for the analog input, the CONVST input

and an external clock input. The use of an external clock source

is optional; there is a shorting plug (LK2) on the ADC CLK in-

put that must be connected to either –5 V (for the ADCs own

internal clock) or to SKT3.

POWER SUPPLY CONNECTIONS

The PCB requires two analog power supplies and one 5 V digi-

tal supply . The analog supplies are labelled V+ and V–, and the

range for both supplies is 12 V to 15 V (see silkscreen in Figure

29). Connection to the 5 V digital supply is made through any

of the connectors (SKT4 to SKT6). The –5 V supply required

by the ADC is generated from a voltage regulator on the V–

power supply input (IC3 in Figure 27).

SHORTING PLUG OPTIONS

There are seven shorting plug options that must be set before

using the board. These are outlined below:

LK1 Connects the analog input to a buffer amplifier. The

analog input may also be connected to a component grid

for signal conditioning.

LK2 Selects either the ADC internal clock or an external

clock source.

LK3 Configures the ADC 12/8/CLK input for the appropri-

ate serial or parallel interface.

LK4 Connects the ADC RD input directly to the two parallel

connectors or to a decoded STRB and R/W input. This

shorting plug setting depends on the microprocessor e.g.,

the TMS32010 has a separate RD output while the

TMS32020 has STRB and R/W outputs.

LK5– Connect the pull-up resistors R3, R4 and R5 to SSTRB,

LK7 SCLK and SDATA. These shorting plugs should be

removed for parallel interfacing.

COMPONENT LIST

IC1 AD711 Op Amp

IC2 AD7870/AD7875/AD7876 Analog-to-

Digital Converter

IC3 MC79L05 –5 V Regulator

IC4 74HC00 Quad NAND Gate

IC5 74HC74 Dual D-Type Flip Flop

C1, C3, C5, C7, 10 µF Capacitors

C9, C11

C2, C4, C6, C8, 0.1 µF Capacitors

C10, C12

R1, R2 10 kΩ Pull-Up Resistors

R3*, R5* 4.7 kΩ Pull-Up Resistors

R4* 2 kΩ Pull-Up Resistor

LK1, LK2 Shorting Plugs

LK3, LK4

LK5, LK6, LK7

SKT1, SKT2, SKT3 BNC Sockets

SKT4 26-Contact (2-Row) IDC Connector

SKT5 9-Contact D-Type Connector

SKT6 96-Contact (3-Row) Eurocard Connector

*Required for Serial Communication only.

REV. B

AD7870/AD7875/AD7876

–17–

Figure 28. Data Acquisition Circuit Using the AD7870/AD7875/AD7876

Figure 29. PCB Silkscreen for Figure 28

REV. B

AD7870/AD7875/AD7876

–18–

Figure 30. PCB Component Side Layout for Figure 28

Figure 31. PCB Solder Side Layout for Figure 28

REV. B

AD7870/AD7875/AD7876

–19–

OUTLINE DIMENSIONS

Dimensions shown in inches and (mm).

24-Pin Plastic DIP (N-24)

24-Pin Cerdip (Q-24)

28-Pin PLCC (P-28A)

24-Pin SOIC (R-24)

C1336–10–8/90

–20–

PRINTED IN U.S.A.