JRC NJU39610FM2, NJU39610D2 Datasheet

MICROSTEPPING MOTOR CONTROLLER WITH DUAL DAC

■ GENERAL DESCRIPTION ■ PACKAGE OUTLINE

NJU39610 is a dual 7-bit+sign, Digital-to-Analog Converter
(DAC) especially developed to be used together with the
NJM3771, Precision Stepper Motor driver in micro-stepping
applications. The NJU39610 has a set of input registers
connected to an 8-bit data port for easy interfacing directly to
a microprocessor. The NJU39610 is well suited for high­speed micro-stepping application.

NJU39610D2 NJU39610FM2

■ FEATURES

• Analog control voltages from 3 V down to 0.0 V

• High-speed microprocessor interface

NJU39610

• Automatic fast/slow current decay control

• Full-scale error ±1 LSB

• Fast conversion speed 3 µs

• Matches NJM3771

• Packages DIP22/PLCC28

■ BLOCK DIAGRAM

WR

CS

A0

A1

D7 - D0

RESET

POR

V

DD

DA- Data 1

E

C

E1

E2

E3

E4

D

R

Level 1

E

C

D

R

Level 2

E

C

D

R

DA- Data 2

E

C

D

R

R

Digit
Comp

Digit
Comp

E1

E4

C

V

Ref

NJU39610

E

C

D

R

E

D

R

D / A

D / A

Sign

CD

DA

DA

CD

Sign

1

1

1

2

2

2

Figure 1. Block Diagram

V

ss

■ PIN CONFIGURATIONS

NJU39610

V

DA

Sign

CD
V

WR

DD

D7
D6
D5
D4
D3

1

ref

2

1

3

1

4

1

5

NJU

39610D2

6

7

8

9

10

11

22

21

20

19

18

17

16

15

14

13

12

Reset
DA

Sign
CD

V

SS

CS
A1

A0
D0
D1
D2

2

2

2

N/C

DA

Reset

N/C
V
DA
N/C

2

ref

1

2

Sign

432

5

6

7

8

39610FM2

9

10

11

12131415161718

1

Sign

2

CD

NJU

1

CD

SS

V

DD

V

CS

1

WR

A0

A1

282726

D7

D6

N/C

N/C

25

D0

24

D1

23

D2

22

N/C

21

D3

20

D4

19

D5

Figure 2. Pin configurations

■ PIN DESCRIPTION

Refer to figure 2.

DIP PLCC Symbol Description

19V
210DA1Digital-to-Analog 1, voltage output. Output between 0.0 V and VR - 1 LSB.
3 12 Sign

Ref

1

413CD1Current Decay 1, TTL/CMOS level. The signal is automatically generated when
514VDDVoltage Drain-Drain, logic supply voltage. Normally +5 V.

6 15 WR Write, TTL/CMOS level, input for writing to internal registers.
7 16 D7 Data 7, TTL/CMOS level, input to set data bit 7 in data word.

8 17 D6 Data 6, TTL/CMOS level, input to set data bit 6 in data word.
9 19 D5 Data 5, TTL/CMOS level, input to set data bit 5 in data word.
10 20 D4 Data 4, TTL/CMOS level, input to set data bit 4 in data word.
11 21 D3 Data 3, TTL/CMOS level, input to set data bit 3 in data word.
12 23 D2 Data 2, TTL/CMOS level, input to set data bit 2 in data word.
13 24 D1 Data 1, TTL/CMOS level, input to set data bit 1 in data word.
14 25 D0 Data 0, TTL/CMOS level, input to set data bit 0 in data word.
15 27 A0 Address 0, TTL/CMOS level, input to select data transfer,

16 28 A1 Address 1, TTL/CMOS level, input to select data transfer. A1 selects between normal
17 1 CS Chip Select, TTL/CMOS level, input to select chip and activate data transfer
18 2 V
19 3 CD
20 4 Sign
21 6 DA

22 7 Reset Reset, digital input resetting internal registers.

SS

2

2

2

5
8
11 N/C Not Connected
18
22
26

Voltage reference supply pin, 2.5 V nominal (3.0 V maximum)
Sign 1, TTL/CMOS level. To be connected directly to NJM3771 Phase input.

Databit D7 is transfered non inverted from NJU39610 data input.
decay level is programmed. LOW level = fast current decay.

Data is clocked into flip flops on positive edge.

A0 selects between cannel 1 (A0 = LOW) and channel 2 (A0 = HIGH).
D/A register programming (A1 = LOW) and decay level register programming (A1 = HIGH).
from data inputs. LOW level = chip is selected.

Voltage Source-Source. Ground pin, 0 V reference for all signals and
measurements unless otherwise noted.
Current Decay 2, TTL/CMOS level. The signal is automatically generated
when decay level is programmed. LOW level = fast current decay .
Sign 2. TTL/CMOS level. To be connected directly to NJM3771 sign input.
Data bit D7 is transfered non-inverted from NJU39610 data input.
Digital-to-Analog 2, voltage output. Output between 0.0 V and V

HIGH level = Reset, V

≥ 3.5 V = HIGH level. Pulled low internally.

Res

- 1 LSB.

ref

NJU39610

■ DEFINITION OF TERMS
Resolution

Resolution is defined as the reciprocal of the number of discrete steps in the DAC output. It is directly related to the
number of switches or bits within the DAC. For example, NJU39610 has 27, or 128, output levels and therefor has 7
bits resolution. Remember that this is not equal to the number of microsteps available.

Linearity Error

Linearity error is the maximum deviation from a straight line passing through the end points of the DAC transfer
characteristic. It is measured after adjusting for zero and full scale. Linearity error is a parameter intrinsic to the
device and cannot be externally adjusted.

Power Supply Sensitivity

Power supply sensitivity is a measure of the effect of power supply changes on the DAC full-scale output

Settling Time

Full-scale current settling time requires zero-to-full-scale or full-scale-to-zero output change. Settling time is the
time required from a code transition until the DAC output reaches within ±1/2LSB of the final output value.

Full-scale ErrorFull-scale error is a measure of the output error between an ideal DAC and the actual device output.

Differential Non-linearity

The difference between any two consecutive codes in the transfer curve from the theoretical 1LSB, is differential
non-linearity

Monotonic

If the output of a DAC increases for increasing digital input code, then the DAC is monotonic. A 7-bit DAC which is
monotonic to 7 bits simply means that increasing digital input codes will produce an increasing analog output.
NJU39610 is monotonic to 7 bits.

■ FUNCTIONAL DESCRIPTION

Each DAC channel contains two registers, a digital comparator, a flip flop, and a D/A converter. A block diagram is
shown on the first page. One of the registers stores the current level, below which, fast current decay is initiated.
The status of the CD outputs determines a fast or slow current decay to be used in the driver.

The digital comparator compares each new value with the previous one and the value for the preset level for fast
current decay. If the new value is strictly lower than both of the others, a fast current decay condition exists. The flip
flop sets the CD output. The CD output is updated each time a new value is loaded into the D/A register. The fast
current decay signals are used by the driver circuit, NJM3771, to change the current control scheme of the output
stages. This is to avoid motor current dragging which occurs at high stepping rates and during the negative current
slopes, as illustrated in figure 9. Eight different levels for initiation of fast current decay can be selected.

The sign outputs generate the phase shifts, i.e., they reverse the current direction in the phase windings.

Output

More
than 2
bits

Negative
difference

Output

Less
than 2
bits

Positive
difference

Output

Actual

Offset error

Gain
error

Correct

Endpoint
non-linearity

Input

Figure 3. Errors in D/A conversion.
Differential non-linearity of more than
1 bit, output is non-monotonic.

Input

Figure 4. Errors in D/A conversion.
Differential non-linearity of less than 1
bit, output is monotonic.

Full scale

Input

Figure 5. Errors in D/A conversion.
Non-linearity, gain and offset errors.

NJU39610

Data Bus Interface

NJU39610 is designed to be compatible with 8-bit microprocessors such as the 6800, 6801, 6803, 6808, 6809,
8051, 8085, Z80 and other popular types and their 16/32 bit counter parts in 8 bit data mode. The data bus inter­face consists of 8 data bits, write signal, chip select, and two address pins. All inputs are TTL-compatible (except
reset). The two address pins control data transfer to the four internal D-type registers. Data is transferred according
to figure 10 and on the positive edge of the write signal.

Current Direction, Sign1 & Sign

2

These bits are transferred from D7 when writing in the respective DA register. A0 and A1 must be set according to
the data transfer table in figure 10.

Current Decay, CD1 & CD

2

CD1 and CD2 are two active low signals (LOW = fast current decay). CD1 is active if the previous value of DA-Data1
is strictly larger than the new value of DA-Data1 and the value of the level register LEVEL1 (L61 … L41) is strictly
larger than the new value of DA-Data1. CD1 is updated every time a new value is loaded into DA-Data1.
The logic definition of CD1 is:

CD1 = NOT{[(D6 … D0) < (Q61 … Q01)] AND[(D6 …D4) < (L61 … L41)]}
Where (D6 … D0) is the new value being sent to DA-Data1 and (Q61 … Q01) is DA-Data1’s old value. (L61 … L41) are

the three bits for setting the current decay level at LEVEL1.

The logic definition of CD2 is analog to CD1:
CD2 = NOT{[(D6 … D0) < (Q62 … Q02)] AND[(D6 …D4) < (L62 … L42)]}
Where (L62 … L42) is the level programmed in channel 2’s level register. (D6 … D0) and (Q62 … Q02) are the new and

old values of DA-Data2.

The two level registers, LEVEL1 and LEVEL2, consist of three flip flops each and they are compared against the
three most significant bits of the DA-Data value, sign bit excluded.

T [mNm]

I [mA]

2

2

T

max

T

nom

T

min

DA output [V]

Current dragging

I

I [mA]

1

Figure 6a. Assuming that torque is
proportional to the current in resp.
winding it is possible to draw figure
8b.

CS A0 A1 Data Transfer
0 0 0 D7 —> Sign1, (D6—D0) —> (Q61—Q01), New value —> CD1
0 0 1 (D6—D4) —> (L61—L41)
0 1 0 D7 —> Sign2, (D6—D0) —> (Q62—Q02), New value —> CD2
0 1 1 (D6—D4) —> (L62—L42)
1 X X No Transfer

Figure 8. Table showing how data is transfered inside NJU39610.

T [mNm]

1

Figure 6b. An example of accessible
positions with a given torque devia­tion/fullstep. Note that 1:st µstep
sets highest resolution. Data points
are exaggerated for illustration
purpose.
TNom = code 127.

CD

t

Time

Figure 7. Motor current dragging at
high step rates and current decay
influence. Fast current decay will
make it possible for the current to
follow the ideal sine curve. Output
shown without sign shift.