ADC-HZ12BGC Murata Power Solutions Inc, ADC-HZ12BGC Datasheet - Page 2

ADC-HZ12BGC

Manufacturer Part Number

ADC-HZ12BGC

Description

Analog To Digital Converter

Manufacturer

Murata Power Solutions Inc

Datasheets

1.ADC-HX12BMM.pdf (6 pages)

2.ADC-HX12BMM.pdf (6 pages)

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Functional Speciﬁcations

PARAMETERS

INPUTS

+15V Supply, Pin 28

–15V Supply, Pin 31

+5V Supply, Pin 16

Digital Inputs, Pins 14, 21

Analog Inputs, Pins 24, 25

Buffer Input, Pin 30

Lead Temperature (10 seconds)

(Typical at +25°C and ±15V and +5V supplies unless otherwise noted)

Analog Input Ranges

Input Impedance

10k (±10V)

Input Impedance with Buffer

Input Bias Current of Buffer

Start Conversion

Resolution

Nonlinearity

Differential Nonlinearity

Accuracy Error

Temperature Coefﬁcient

Diff. Nonlinearity Tempco

No Missing Codes

Conversion Time

Buffer Settling Time (10V step)

Power Supply Rejection

Parallel Output Data

command.

Unipolar Coding

Bipolar Coding

Complementary two’s complement

Serial Output Data

Compl. binary or compl. offset binary coding.

End of Conversion (Status)

during reset and conversion and logic "0"

when conversion complete.

Clock Output

for ADC-HX and 1.5MHz for

ADC-HZ (pin 17 grounded).

Internal Reference

Reference Tempco

External Reference Current

Gain (before adjustment)

Zero, Unipolar (before adj.)

Offset, Bipolar (before adj.)

Gain

Zero, Unipolar

Offset, Bipolar

12 Bits

10 Bits

8 Bits

Unipolar

Bipolar

5k (0 to +10V, ±5V)

OUT

("0") +0.4V

("1") +2.4V

ABSOLUTE MAXIMUM RATINGS

OUTPUTS

PERFORMANCE

ADC-HX12B

0 to +5V, 0 to +10V

±2.5V, ±5V, ±10V

2.5k (0 to +5V, ±2.5V)

50 megohms

125nA typical, 250nA max.

+2V min. to +5.5V max. positive pulse with dur-

ation of 100ns min. Rise and fall times <30ns.

Logic "1" to "0" transition resets converter and

initiates next conversion. Loading: 2 TTL loads.

12 bits

±1/2LSB max.

±3/4LSB max.

±0.2%

±0.1% of FSR

±0.2% of FSR

±20ppm/°C max.

±5ppm/°C of FSR max.

±10ppm/°C of FSR max.

±2ppm/°C of FSR max.

Over opererating temperature range

20μs max.

15μs max.

10μs max.

3μs to ±0.01%

±0.004%/% supply max.

12 parallel lines of data held until next conversion

Complementary binary

Complementary offset binary

NRZ successive decision pulses out, MSB ﬁrst.

Conversion status signal. Output is logic "1"

Train of positive going +5V 100ns pulses. 600kHz

+6.3V

±20ppm/°C max.

2.5mA max.

LIMITS

±5.5

+18

–18

±25

±15

300

www.murata-ps.com

ADC-HZ12B

8μs max.

6μs max.

4μs max.

UNITS

Volts

°C

PHYSICAL/ENVIRONMENTAL

Footnotes:

TECHNICAL NOTES

12-Bit, 8 and 20μsec Analog-to-Digital Converters

Power Supply Voltages

–15V ±0.5V at –25mA

+5V ±0.25V at +85mA

Operating Temp. Range, Case

Storage Temperature Range

Package Type

Weight

Thermal Impedance

Adjustable to zero.

FSR is full scale range and is 10V for 0 to +10V or ±5V inputs and 20V for

±10V input, etc.

Without buffer ampliﬁer used. ADC-HZ may require external adjustment

of clock rate.

Short cycled operation.

All digital outputs can drive 2 TTL loads.

It is recommended that the ±15V power input pins both be bypassed to ground with a 0.01μF ceramic

capacitor in parallel with a 1μF electrolytic capacitor and the +5V power input pin be bypassed to ground

with a 10μF electrolytic capacitor as shown in the connection diagrams. In addition, GAIN ADJUST (pin 27)

should be bypassed to ground with a 0.01μF ceramic capacitor. These precautions will assure noise free

operation of the converter.

DIGITAL COMMON (pin 15) and ANALOG COMMON (pin 26) are not connected together internally, and

therefore must be connected as directly as possible externally. It is recommended that a ground plane be

run underneath the case between the two commons. Analog ground and ±15V power ground should be

run to pin 26 whereas digital ground and +5V ground should be run to pin 15.

External adjustment of zero or offset and gain are made by using trimming potentiometers connected as

shown in the connection diagrams. The potentiometer values can be between 10k and 100k Ohms and

should be 100ppm/°C cermet types. The trimming pots should be located as close as possible to the con-

verter to avoid noise pickup. In some cases, for example 8-bit short-cycled operation, external adjustment

may not be necessary.

Short-cycled operation results in shorter conversion times when the conversion is truncated to less than

12 bits. This is done by connecting SHORT CYCLE (pin 14) to the output bit following the last bit desired.

For example, for an 8-bit conversion, pin 14 is connected to the bit 9 output. Maximum conversion times

are given for short-cycled conversions of 8 or 10 bits. In these two cases, the clock rate is accelerated by

connecting the CLOCK RATE adjust (pin 17) to +5V (10 bits) or +15V (8 bits). The clock rate should not be

arbitrarily speeded up to exceed the maximum conversion rate at a given resolution, as missing codes will

result.

Note that output coding is complementary coding. For unipolar operation it is complementary binary, and

for bipolar operation it is complementary offset binary or complementary two’s complement. In cases in

which bipolar coding of offset binary or two’s complement is required, this can be achieved by inverting the

analog input to the converter (using an op amp connected for gain of –1). The converter is then calibrated

so that –FS analog input gives an output code of 0000 0000 0000, and +FS – 1LSB gives 1111 1111 1111.

These converters can be operated with an external clock. To accomplish this, a negative pulse train is

applied to START CONVERT (pin 21). The rate of the external clock must be lower than the rate of the

internal clock as adjusted (see Short Cycle Operation tables) for the converter resolution selected. The

pulse width of the external clock should be between 100 and 300 nanoseconds. Each N-bit conversion

cycle requires a pulse train of N + 1 clock pulses for completion, e.g., an 8-bit conversion requires 9 clock

pulses for completion. A continuous pulse train may be used for consecutive conversions, resulting in an

N-bit conversion every N + 1 pulses, or the E.O.C. output may be used to gate a continuous pulse train for

single conversions.

When the input buffer ampliﬁer is used, a delay equal to its settling time must be allowed between the input

level change, such as a multiplexer channel change, and the negative-going edge of the START CONVERT

pulse. If the buffer is not required, BUFFER INPUT (pin 30) should be tied to ANALOG COMMON (pin 26). This

prevents the unused ampliﬁer from introducing noise into the converter. For applications not using the buffer,

the converter must be driven from a source with an extremely low output impedance.

ADC-HX, ADC-HZ Series

Technical enquiries email: sales@murata-ps.com, tel:

POWER REQUIREMENTS

+15V ±0.5V at +20mA

0 to +70°C or –55 to +125°C

–65 to +150°C

32-pin ceramic TDIP

0.5 ounces (14 grams)

6°C/W

30°C/W

MDA_ADCHXHZ.B01 Page 2 of 6

+1 508 339 3000

ADC-HZ12BGC Murata Power Solutions Inc, ADC-HZ12BGC Datasheet - Page 2

ADC-HZ12BGC

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