Freescale MC33976DWR2 Dual gauge driver with configurable esponse time Datasheet

Freescale Semiconductor
Advance Information
Document Number: MC33976
Rev 4.0, 1/2007
Dual Gauge Driver with
Configurable Response Time
33976
The 33976 is a single-packaged, Serial Peripheral Interface (SPI)
controlled, dual step motor gauge driver integrated circuit (IC). This
monolithic IC consists of four dual output H-Bridge coil drivers and the
associated control logic. Each pair of H-Bridge drivers is used to
automatically control the speed, direction, and magnitude of current
through the two coils of a two-phase instrumentation step motor,
similar to an MMT-licensed AFIC 6405 or Switec MS-X15.xxx motor.
CONFIGURABLE DUAL GAUGE DRIVER
The 33976 is ideal for use in automotive instrumentation systems
requiring distributed and flexible step motor gauge driving. The
device also eases the transition to step motors from air core motors
by emulating the air core pointer movement with little additional
processor bandwidth utilization.
Features
•MMT-Licensed Two-Phase Step Motor Compatible
•Switec MS-X15.xxx Step Motor Compatible
•Minimal Processor Overhead Required
•Fully Integrated Pointer Movement and Position State Machine
with Channel-Independent Configurable Pointer Movement
•4096 Possible Steady State Pointer Positions
•340° Maximum Pointer Sweep
DW SUFFIX
EG SUFFIX (PB-FREE)
98ASB42344B
24-PIN SOICW
ORDERING INFORMATION
4500°/s2
•Maximum Acceleration of
•Maximum Pointer Velocity of 400°/s
•Analog Microstepping (12 Steps/Degree of Pointer Movement)
•Pointer Calibration and Return to Zero (RTZ)
•SPI-Controlled 16-Bit Word
•Calibratable Internal Clock
•Low Sleep Mode Current
•Pb-Free Packaging Designated by Suffix Code EG
Device
MCZ33976EG/R2
33976
VPWD
VDD
VDD
SIN0+
SIN0Motor 0
COS0+
COS0-
MCU
RTZ
RST
CS
SCLK
SI
SO
GND
SIN1+
SIN1Motor 1
COS1+
COS1-
Figure 1. 33976 Simplified Application Diagram
* This document contains certain information on a new product.
Specifications and information herein are subject to change without notice.
© Freescale Semiconductor, Inc., 2007. All rights reserved.
Package
- 40°C to 125°C
24 SOICW
MC33976DW/R2
VPWR
5.0 V
Regulator
Temperature
Range (TA)
INTERNAL BLOCK DIAGRAM
INTERNAL BLOCK DIAGRAM
VPWR
VDD
CS
SCLK
SO
SI
RST
INTERNAL
REGULATOR
COS0
COS0+
COS0-
SIN0
SIN0+
SIN0-
COS1
COS1+
COS1-
SPI
LOGIC
STATE
MACHINE
UNDERAND
OVERVOLTAGE
DETECT
H-BRIDGE
AND
CONTROL
ILIM
OVERTEMPERATURE
DETECT
SIGMA-DELTA
ADC
SIN1+
SIN1-
SIN1
VDD
MULTIPLEXER
OSCILLATOR
AGND
RTZ
GND (8)
Figure 2. 33976 Simplified Internal Block Diagram
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Analog Integrated Circuit Device Data
Freescale Semiconductor
PIN CONNECTIONS
PIN CONNECTIONS
COS0+
COS0SIN0+
SIN0GND
GND
GND
GND
CS
SCLK
SO
SI
1
24
2
23
3
22
4
21
5
20
6
19
7
18
8
17
9
16
10
15
11
14
12
13
COS1+
COS1SIN1+
SIN1GND
GND
GND
GND
VPWR
RST
VDD
RTZ
Figure 3. 33976 Pin Connections
Table 1. 33976 Pin Definitions
Pin
Number
Pin
Name
Pin
Function
Formal Name
Definition
(MS Motor Pin #)
Output
H-Bridge Outputs 0
Each pin is the output pin of a half bridge, designed to source or sink
current.
These pins serve as the ground for the source of the low-side output
transistors as well as the logic portion of the device.
1
2
3
4
COS0+ (MS #4)
COS0− (MS #3)
SIN0+(MS #1)
SIN0− (MS #2)
5 – 8,
17– 20
GND
Ground
Ground
9
CS
Input
Chip Select
This pin is connected to a chip select output of a LSI IC.
10
SCLK
Input
Serial Clock
This pin is connected to the SCLK pin of the master device and acts
as a bit clock for the SPI port.
11
SO
Output
Serial Output
This pin is connected to the SPI Serial Data Input pin of the master
device or to the SI pin of the next device in a daisy chain.
12
SI
Input
Serial Input
This pin is connected to the SPI Serial Data Output pin of the master
device from which it receives output command data.
13
RTZ
Output
Multiplexed Output
This is a multiplexed output pin for the non-driven coil, during a Return
to Zero (RTZ) event.
14
VDD
Input
Voltage
This SPI and logic power supply input will work with 5.0 V supplies.
15
RST
Input
Reset
16
VPWR
Input
Battery Voltage
(MS Motor Pin #)
Output
H-Bridge Outputs 1
21
22
23
24
SIN1− (MS #2)
SIN1+ (MS #1)
COS1− (MS #3)
COS1+ (MS #4)
This input has an internal active pull-up.
Power supply.
Each of these pins is the output pin of a half bridge, designed to
source or sink current.
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Freescale Semiconductor
3
ELECTRICAL CHARACTERISTICS
MAXIMUM RATINGS
ELECTRICAL CHARACTERISTICS
MAXIMUM RATINGS
Table 2. Maximum Ratings
All voltages are with respect to ground unless otherwise noted. Exceeding these ratings may cause a malfunction or
permanent damage to the device.
Rating
Power Supply Voltage
Symbol
VPWR(SUS)
Steady State
Input Pin Voltage (1)
SIN +/- COS +/- Continuous Per Output Current (2)
Storage Temperature
Operating Junction Temperature
Value
V
-0.3 to 41
VIN
-0.3 to 7.0
V
IOUTMAX
40
mA
TSTG
-55 to 150
°C
TJ
-40 to 150
°C
Thermal Resistance
°C/W
Junction to Ambient
RθJA
60
Junction to Lead
RθJL
20
Human Body Model
VESD1
±2000
Machine Model
VESD2
±200
TPPRT
Note 5
ESD Voltage (3)
Peak Package Reflow Temperature During Reflow (4), (5)
Unit
V
°C
Notes
1. Exceeding voltage limits on Input pins may cause permanent damage to the device.
2. Output continuous output rating so long as maximum junction temperature is not exceeded. Operation at 125°C ambient temperature will
require maximum output current computation using package thermal resistances.
3. ESD1 testing is performed in accordance with the Human Body Model (CZAP = 100 pF, RZAP = 1500 Ω), ESD2 testing is performed in
accordance with the Machine Model (CZAP = 200 pF, RZAP = 0 Ω).
4.
5.
Pin soldering temperature limit is for 10 seconds maximum duration. Not designed for immersion soldering. Exceeding these limits may
cause malfunction or permanent damage to the device.
Freescale’s Package Reflow capability meets Pb-free requirements for JEDEC standard J-STD-020C. For Peak Package Reflow
Temperature and Moisture Sensitivity Levels (MSL),
Go to www.freescale.com, search by part number [e.g. remove prefixes/suffixes and enter the core ID to view all orderable parts. (i.e.
MC33xxxD enter 33xxx), and review parametrics.
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Freescale Semiconductor
ELECTRICAL CHARACTERISTICS
STATIC ELECTRICAL CHARACTERISTICS
STATIC ELECTRICAL CHARACTERISTICS
Table 3. Static Electrical Characteristics
Characteristics noted under conditions 4.75 V ≤ VDD ≤ 5.25 V, - 40°C ≤ TJ ≤ 150°C, GND = 0 V unless otherwise noted.
Typical values noted reflect the approximate parameter means at TA = 25°C under nominal conditions unless otherwise noted.
Characteristic
Symbol
Min
Typ
Max
Unit
Fully Operational
6.5
–
26
Limited Operational (6), (7)
4.0
–
26
–
4.0
6.0
IPWSLP1
–
42
60
Reset = Logic [0], VDD = 0 V
IPWRSLP2
–
15
25
Overvoltage Detection Level (8)
VPWROV
26
32
38
V
Undervoltage Detection Level (9)
VPWRUV
5.0
5.6
6.2
V
VDD
4.5
5.0
5.5
V
VDDUV
–
–
4.5
V
Sleep: Reset Logic [0]
IDD(OFF)
–
40
65
µA
Outputs Enabled
IDD(ON)
–
1.0
1.8
mA
POWER INPUT
Supply Voltage Range
VPWR Supply Current
VPWR
V
IPWR(ON)
Gauge 1 and 2 Outputs ON, No Output Loads
mA
µA
VPWR Supply Current (All Outputs Disabled)
Reset = Logic [0], VDD = 5.0 V
Logic Supply Voltage Range (5.0 V Nominal Supply)
Under VDD Logic Reset
VDD Supply Current
POWER OUTPUTS
Microstep Output (Measured Across Coil Outputs)
V
SIN0,1, ± (COS0,1, ±) (refer to Table 1)
ROUT = 200 Ω, PE6 = 0
Steps 6, 18 (0, 12)
VST6
4.82
5.3
6.0
Steps 5, 7, 17, 19 (1, 11, 13, 23)
VST5
0.94 VST6
0.97 VST6
1.0 VST6
Steps 4, 8, 16, 20 (2, 10, 14, 22)
VST4
0.84 VST6
0.87 VST6
0.96 VST6
Steps 3, 9, 15, 21 (3, 9, 15, 21)
VST3
0.68 VST6
0.71 VST6
0.8 VST6
VST2
0.47 VST6
0.50 VST6
0.57 VST6
VST1
0.23 VST6
0.26 VST6
0.31 VST6
VST0
-0.1
0
0.1
Steps 2, 10, 14, 22 (4, 8,16, 20)
Steps 1, 11, 13, 23 (5, 7, 17, 19)
Steps 0, 12 (6, 18)
Notes
6. Outputs and logic remain active; however, the larger coil voltage levels may be clipped. The reduction in drive voltage may result in a
loss of position control.
7. The logic will reset at some level below the specified Limited Operational minimum.
8. Outputs will disable and must be re-enabled via the PECCR command.
9. Outputs remain active; however, the reduction in drive voltage may result in a loss of position control.
33976
Analog Integrated Circuit Device Data
Freescale Semiconductor
5
ELECTRICAL CHARACTERISTICS
STATIC ELECTRICAL CHARACTERISTICS
Table 3. Static Electrical Characteristics (continued)
Characteristics noted under conditions 4.75 V ≤ VDD ≤ 5.25 V, - 40°C ≤ TJ ≤ 150°C, GND = 0 V unless otherwise noted.
Typical values noted reflect the approximate parameter means at TA = 25°C under nominal conditions unless otherwise noted.
Characteristic
Symbol
Min
Typ
Max
Unit
POWER OUTPUTS (CONTINUED)
Full Step Active Output (Measured Across Coil Outputs)
VFS
V
SIN0, 1, ± (COS0, 1, ±) (see Figure 9, page 26)
Steps 1, 3 (0, 2)
4.9
Microstep, Full Step Output
5.3
6.0
VLS
V
(Measured from Coil Low Side to Ground)
SIN0, 1, ± (COS0, 1, ±), IOUT = 30 mA
0
0.1
0.3
Output Flyback Clamp (11)
VFB
–
VST6 + 0.5
VST6+ 1.0
V
Output Current Limit (Output = Vst6)
ILIM
40
100
170
mA
Overtemperature Shutdown (10)
OTSD
155
–
180
°C
Overtemperature Hysteresis (11)
OTHYST
8.0
–
16
°C
Input Logic High Voltage (12)
VIH
2.0
–
–
V
Input Logic Low Voltage (12)
VIL
–
–
0.8
V
VIN(HYST)
–
100
–
mV
IDWN
3.0
–
20
µA
IUP
5.0
–
20
µA
SO High-State Output Voltage (IOH = 1.0 mA)
VSOH
0.8 VDD
–
–
V
SO Low-State Output Voltage (IOL = -1.6 mA)
VSOL
–
0.2
0.4
V
SO Tri-State Leakage Current (CS ≥ 3.5 V)
ISOLK
-5.0
0
5.0
µA
Input Capacitance (13)
CIN
–
4.0
12
pF
SO Tri-State Capacitance (13)
CSO
–
–
20
pF
GADC
100
188
270
Counts/
V/ms
CONTROL I/O
Input Logic Voltage Hysteresis (10)
Input Logic Pull Down Current (SI, SCLK)
Input Logic Pull-Up Current (CS, RST)
ANALOG TO DIGITAL CONVERTER (RTZ ACCUMULATOR COUNT)
ADC Gain (10), (14)
Notes
10. This parameter is guaranteed by design, but it is not production tested.
11. Not 100 percent tested.
12. VDD = 5.0 V.
13.
14.
Capacitance not measured. This parameter is guaranteed by design, but it is not production tested.
Reference RTZ Accumulator (Typical) on page 23
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ELECTRICAL CHARACTERISTICS
DYNAMIC ELECTRICAL CHARACTERISTICS
DYNAMIC ELECTRICAL CHARACTERISTICS
Table 4. Dynamic Electrical Characteristics
Characteristics noted under conditions 4.75 V ≤ VDD ≤ 5.25 V, - 40°C ≤ TJ ≤ 150°C, GND = 0 V unless otherwise noted.
Typical values noted reflect the approximate parameter means at TA = 25°C under nominal conditions unless otherwise noted.
Characteristic
Symbol
Min
Typ
Max
Units
POWER OUTPUT AND CLOCK TIMINGS
SIN0,1, ± (COS0,1, ±) Output Turn ON Delay Time
tDLY (ON)
ms
(Time from Rising CS Enabling
1.0
Outputs to Steady State Coil Voltages and Currents) (15)
SIN0,1, ± (COS0,1, ±) Output Turn OFF Delay Time (Time from Rising CS
Disables Outputs to Steady State Coil Voltages and Currents) (15)
–
–
tDLY (OFF)
ms
–
–
1.0
0.65
1.0
1.7
Calibration Pulse = 8.0 µs, PECCR D4 = Logic [0]
1.0
1.1
1.2
Calibration Pulse = 8.0 µs, PECCR D4 = Logic [1]
0.9
1.0
1.1
Uncalibrated Oscillator Cycle Time
tCLU
Calibrated Oscillator Cycle Time
tCLC
µs
µs
Maximum Pointer Speed (16)
VMAX
–
–
400
°/s
Maximum Pointer Acceleration (16)
A MAX
–
–
4500
°/s2
Notes
15. Maximum specified time for the 33976 is the minimum guaranteed time needed from the microcontroller.
16. The minimum and maximum value will vary proportionally to the internal clock tolerance. These numbers are based on an ideally
calibrated clock frequency of 1.0 MHz. These are not 100 percent tested.
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Analog Integrated Circuit Device Data
Freescale Semiconductor
7
ELECTRICAL CHARACTERISTICS
DYNAMIC ELECTRICAL CHARACTERISTICS
Table 4. Dynamic Electrical Characteristics (continued)
Characteristics noted under conditions 4.75 V ≤ VDD ≤ 5.25 V, - 40°C ≤ TJ ≤ 150°C, GND = 0 V unless otherwise noted.
Typical values noted reflect the approximate parameter means at TA = 25°C under nominal conditions unless otherwise noted.
Characteristic
Symbol
Min
Typ
Max
Units
fSPI
–
1.0
2.0
MHz
Falling Edge of CS to Rising Edge of SCLK (Required Setup Time) (18)
tLEAD
–
50
167
ns
Falling Edge of SCLK to Rising Edge of CS (Required Setup Time) (18)
tLAG
–
50
167
ns
SI to Falling Edge of SCLK (Required Setup Time) (18)
tSISU
–
25
83
ns
Required High State Duration of SCLK (Required Setup Time (18)
tWSCLKH
–
–
167
ns
Required Low State Duration of SCLK (Required Setup Time (18)
tWSCLKL
–
–
167
ns
Falling Edge of SCLK to SI (Required Hold Time) (18)
tSI (HOLD)
–
25
83
ns
–
25
50
–
25
50
tRSI
–
–
50
ns
SPI INTERFACE TIMING (17)
Recommended Frequency of SPI Operation
SO Rise Time
tRSO
CL = 200 pF
SO Fall Time
tFSO
CL = 200 pF
SI, CS, SCLK, Incoming Signal Rise Time (19)
SI, CS, SCLK, Incoming Signal Fall Time
ns
(19)
tFSI
–
–
50
ns
(18)
tWRST
–
–
3.0
µs
(18), (20)
t CS
–
–
5.0
µs
Falling Edge of RST to Rising Edge of RST (Required Setup Time)
Rising Edge of CS to Falling Edge of CS (Required Setup Time)
ns
(18)
tEN
–
–
5.0
µs
Time from Falling Edge of CS to SO Low Impedance
(21)
tSO(EN)
–
–
145
ns
Time from Rising Edge of CS to SO High Impedance
(22)
tSO(DIS)
–
1.3
4.0
µs
–
90
150
Rising Edge of RST to Falling Edge of CS (Required Setup Time)
Time from Rising Edge of SCLK to SO Data Valid
0.2 VDD ≤ SO ≥ 0.8 VDD, CL = 200 pF
(23)
tVALID
ns
Notes
17. The 33976 shall meet all SPI interface timing requirements specified in the SPI Interface Timing section of this table, over the specified
temperature range. Digital interface timing is based on a symmetrical 50 percent duty cycle SCLK Clock Period of 333 ns. The device
shall be fully functional for slower clock speeds. Reference Figure 4 and 5.
18. The maximum setup time specified for the 33976 is the minimum time needed from the microcontroller to guarantee correct operation.
19. Rise and Fall time of incoming SI, CS, and SCLK signals suggested for design consideration to prevent the occurrence of double pulsing.
20. The value is for a 1.0 MHz calibrated internal clock. The value will change proportionally as the internal clock frequency changes.
21. Time required for output status data to be terminated at SO. 1.0 kΩ load on SO
22. Time required for output status data to be available for use at SO. 1.0 kΩ load on SO.
23. Time required to obtain valid data out from SO following the rise of SCLK.
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Analog Integrated Circuit Device Data
Freescale Semiconductor
ELECTRICAL CHARACTERISTICS
TIMING DIAGRAMS
TIMING DIAGRAMS
VIN
RST
0.2 VDD
VIL
tWRST
tCS
tEN
VIH
0.7 VDD
CS
0.7 VDD
VIL
tWSCLKH
tLEAD
tRSI
tLAG
VIH
0.7 VDD
SCLK
0.2 VDD
VIL
tLEAD
SI
0.7 VDD
0.2 VDD
Don’t Care
tWSCLKL
tSI(HOLD)
tFSI
VIH
Valid
Don’t Care
Valid
Don’t Care
VIL
Figure 4. Input Timing Switching Characteristics
tRSI
tFSI
VOH
3.5 V
SCLK
50%
1.0 V
tSO(EN)
0.7 VDD
SO
VOL
VOH
0.2 VDD
VOL
Low-to-High
trSO
tVALID
SO
tfSO
High-to-Low
VOH
0.7 VDD
tSO(DIS)
0.2 VDD
VOL
Figure 5. Valid Data Delay Time and Valid Time Waveforms
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Freescale Semiconductor
9
FUNCTIONAL DESCRIPTION
INTRODUCTION
FUNCTIONAL DESCRIPTION
INTRODUCTION
This 33976 is a single-packaged, Serial Peripheral
Interface (SPI) controlled, dual step motor gauge driver
integrated circuit (IC). This monolithic IC consists of four dual
output H-Bridge coil drivers and the associated control logic.
Each pair of H-Bridge drivers is used to automatically control
the speed, direction, and magnitude of current through the
two coils of a two-phase instrumentation step motor, similar
to an MMT-licensed AFIC 6405 or a Switec MS-X15.xxx
motor.
The 33976 is ideal for use in automotive instrumentation
systems requiring distributed and flexible step motor gauge
driving. The device also eases the transition to step motors
from air core motors by emulating the air core pointer
movement with little additional processor bandwidth
utilization.
FUNCTIONAL PIN DESCRIPTION
H-BRIDGE OUTPUTS 0 (COS0+, COS0-, SIN0+,
SIN0-)
Each pin is the output pin of a half bridge, designed to
source or sink current. The H-Bridge pins linearly drive the
sine and cosine coils of two separate step motors to provide
four-quadrant operation.
GROUND (GND)
These pins serve as the ground for the source of the lowside output transistors as well as the logic portion of the
device. They also help dissipate heat from the device.
CHIP SELECT (CS)
The CS pin enables communication with the master
device. When this pin is in a logic [0] state, the 33976 is
capable of transferring information to, and receiving
information from, the master. The 33976 latches data in from
the Input Shift registers to the addressed registers on the
rising edge of CS. The output driver on the SO pin is enabled
when CS is logic [0]. When CS is logic high, signals at the
SCLK and SI pins are ignored and the SO pin is tri-stated
(high impedance). CS will only be transitioned from a logic [1]
state to a logic [0] state when SCLK is a logic [0]. CS has an
internal pull-up (lUP) connected to the pin, as specified in the
section of the Static Electrical Characteristics table entitled
CONTROL I/O, which is found on page 6.
and SO is tri-stated (high impedance). Refer to the data
transfer timing diagrams in Figure 6 and Figure 7 on page 12.
SERIAL OUTPUT (SO)
The SO data pin is a tri-stateable output from the Shift
register. The Status register bits are the first 16 bits shifted
out. Those bits are followed by the message bits clocked in
FIFO, when the device is in a daisy chain connection or being
sent words that are multiples of 16 bits. Data is shifted on the
rising edge of the SCLK signal. The SO pin will remain in a
high impedance state until the CS pin is put into a logic low
state.
SERIAL INPUT (SI)
The SI pin is the input of the SPI. Serial input information
is read on the falling edge of SCLK. A 16-bit stream of serial
data is required on the SI pin, beginning with the most
significant bit (MSB). Messages that are not multiples of 16
bits (e.g., daisy chained device messages) are ignored. After
transmitting a 16-bit word, the CS pin must be de-asserted
(logic [1]) before transmitting a new word. SI information is
ignored when CS is in a logic high state.
MULTIPLEXED OUTPUT (RTZ)
This is a multiplexed output pin for the non-driven coil,
during a Return to Zero (RTZ) event.
SERIAL CLOCK (SCLK)
VOLTAGE (VDD)
SCLK clocks the Internal Shift registers of the 33976
device. The SI pin accepts data into the Input Shift register on
the falling edge of the SCLK signal, while the Serial Output
pin (SO) shifts data information out of the SO Line Driver on
the rising edge of the SCLK signal. It is important that the
SCLK pin be in a logic [0] state whenever the CS makes any
transition. SCLK has an internal pull down (lDWN), as
specified in the section of the Static Electrical Characteristics
table entitled CONTROL I/O, which is found on page 6. When
CS is logic [1], signals at the SCLK and SI pins are ignored
This SPI and logic power supply input will work with 5.0 V
supplies.
RESET (RST)
If the master decides to reset the device or place it into a
sleep state, the RST pin is driven to a logic [0]. A logic [0] on
the RST pin will force all internal logic to the known default
state. This input has an internal active pull-up.
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Analog Integrated Circuit Device Data
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FUNCTIONAL DESCRIPTION
FUNCTIONAL PIN DESCRIPTION
BATTERY VOLTAGE (VPWR)
Power supply.
H-BRIDGE OUTPUTS 1 (SIN1-, SIN1+, COS1-,
COS1+)
Each of these pins is the output pin of a half bridge,
designed to source or sink current. The H-Bridge pins linearly
drive the sine and cosine coils of two separate step motors to
provide four-quadrant operation.
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Freescale Semiconductor
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FUNCTIONAL DEVICE OPERATION
OPERATIONAL MODES
FUNCTIONAL DEVICE OPERATION
OPERATIONAL MODES
SPI PROTOCOL DESCRIPTION
(SO). The SI/SO pins of the 33976 follow a first in/first out
(D15/D0) protocol with both input and output words
transferring the most significant bit first. All inputs are
compatible with 5.0 V CMOS logic levels.
The SPI interface has a full-duplex, three-wire
synchronous, 16-bit serial synchronous interface data
transfer and four I/O lines associated with it: Chip Select (CS),
Serial Clock (SCLK), Serial Input (SI), and Serial Output
TIMING DESCRIPTION
This section provides a description of the 33976 SPI
behavior. To follow the explanations below, refer to Table 5
and to the timing diagrams shown in Figure 6 and Figure 7.
Table 5. Data Transfer Timing
Pin
Description
CS (1-to-0)
SO pin is enabled.
CS (0-to-1)
33976 configuration and desired output states are transferred and executed according to the data
in the Shift registers.
SO
Will change state on the rising edge of the SCLK pin signal.
SI
Will accept data on the falling edge of the SCLK pin signal.
CS
SCLK
SI
SO
D15
D14
D13
D12
D11
D10
OD15
OD14
OD13
OD12
OD11
OD10
D9
OD9
D8
OD8
D7
OD7
D6
OD6
D5
OD5
D4
D3
OD4
OD3
D2
D0
D1
OD2
OD1
OD0
Output shift register is loaded here.
Note SO is tri-stated when CS is logic [1].
Figure 6. Single 16-Bit Word SPI Communication
CS
SCLK
SI
SO
D15
D14
D13
D12
D11
D2
OD15
OD14
OD13
OD12
OD11
OD2
D1
OD1
D0
OD0
D15*
D15
D14*
D14
D13*
D13
D4
D3
OD4
OD3
D2*
D2
D1*
D1
D0*
D0
Notes 1. SO is tri-stated when CS is logic [1].
2. D15, D14, D13, ..., and D0 refer to the first 16 bits of data into the 33976.
3. D15*, D14*, D13*, ..., and D0* refer to the most recent entry of program data into the 33976.
4. OD15, OD14, OD13, ..., and OD0 refer to the first 16 bits of fault and status data out of the 33976.
Figure 7. Multiple 16-Bit Word SPI Communication
33976
12
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
DATA INPUT
The Input Shift register captures data at the falling edge of
the SCLK clock. The SCLK clock pulses exactly 16 times only
inside the transmission windows (CS in a logic [0] state). By
the time the CS signal goes to logic [1] again, the contents of
the Input Shift register are transferred to the appropriate
internal register addressed in bits 15:13. The minimum time
CS should be kept high depends on the internal clock speed,
specified in the SPI INTERFACE TIMING (17) section of the
Static Electrical Characteristics, found on page 6. It must be
long enough so the internal clock is able to capture the data
from the Input Shift register and transfer it to the internal
registers.
DATA OUTPUT
At the first rising edge of the SCLK clock, with CS at
logic [0], the contents of the selected Status Word register
are transferred to the Output Shift register. The first 16 bits
clocked out are the status bits. If data continues to clock in
before the CS transitions to a logic [1], the device begins to
shift out the data previously clocked in FIFO after the CS first
transitioned to logic [0].
LOGIC COMMANDS AND REGISTERS
COMMUNICATION MEMORY MAPS AND REGISTER DESCRIPTIONS
The 33976 device is capable of interfacing directly with a
microcontroller via the 16-bit SPI protocol specified below.
The device is controlled by the microprocessor and reports
back status information via the SPI. This section provides a
detailed description of all registers accessible via serial
interface. The various registers control the behavior of this
device.
A message is transmitted by the master beginning with the
MSB (D15) and ending with the LSB (D0). Multiple messages
can be transmitted in succession to accommodate those
applications where daisy chaining is desirable, or to confirm
transmitted data, as long as the messages are all multiples of
16 bits. Data is transferred through daisy-chained devices, as
illustrated in Figure 7, page 12. If an attempt is made to latch
in a message smaller than 16 bits wide, it is ignored.
Table 6 lists the seven registers the 33976 uses to
configure the device, control the state of the four H-bridge
outputs, and determine the type of status information that is
clocked back to the master. The registers are addressed via
D15:D13 of the incoming SPI word.
Table 6. Module Memory Map
Address
[15:13]
Register
Name
See Page
000
Power, Enable, Calibration,
and Configuration Register
PECCR
Page 13
001
Maximum Velocity Register
VELR
Page 15
010
Gauge 0 Position Register
POS0R
Page 16
011
Gauge 1 Position Register
POS1R
Page 16
100
Return to 0 Register
RTZR
Page 16
101
Return to 0
Configuration Register
RTZCR
Page 17
110
Ramp Selection Register
RMPSELR
Page 19
111
Reserved for Test
–
–
MODULE MEMORY MAP
Various registers of the 33976 SPI module are addressed
by the three MSBs of the 16-bit word received serially.
Functions to be controlled include:
• Individual gauge drive enabling
• Power-up/down
• Internal clock calibration
• Gauge pointer position and velocity
• Gauge pointer zeroing
• Air core motor movement emulation
• Status information
Status reporting includes:
• Individual gauge overtemperature condition
• Battery overvoltage
• Battery undervoltage
• Pointer zeroing status
• Internal clock status
• Confirmation of coil output changes that should result in
pointer movement
• Real time pointer position information
• Real time pointer velocity step information
• Pointer movement direction
• Command pointer position status
• RTZ accumulator value
REGISTER DESCRIPTIONS
The following section describes the registers, their
addresses, and their impact on device operation.
Address 000 — Power, Enable, Calibration, and
Configuration Register (PECCR)
The Power, Enable, Calibration, and Configuration
Register is illustrated in Table 7, page 14. A write to the
33976 using this register allows the master to
(1) independently enable or disable the output drivers of the
two-gauge controllers, (2) calibrate the internal clock,
(3) disable the air core emulation, (4) select the direction of
the pointer movement during pointer positioning and zeroing,
(5) configure the device for the desired status information to
33976
Analog Integrated Circuit Device Data
Freescale Semiconductor
13
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
be clocked out into the SO pin, or (6) send a null command
for the purpose of reading the status bits. This register is also
used to place the 33976 into a low current consumption
mode.
Each of the gauge drivers can be enabled by writing a
logic [1] to their assigned address bits, PE0 and PE1
respectively. This feature could be used to disable a driver if
it is failing or is not being used. The device can be placed into
a standby current mode by writing a logic [0] to both PE0 and
PE1. During this state, most current consuming circuits are
biased off. When in the Standby mode, the internal clock will
remain ON.
The internal state machine utilizes a ROM table of step
times defining the duration that the motor will spend at each
microstep as it accelerates or decelerates to a commanded
position. The accuracy of the acceleration and velocity of the
motor is directly related to the accuracy of the internal clock.
Although the accuracy of the internal clock is temperature
independent, the non-calibrated tolerance is +70% to -35%.
The 33976 was designed with a feature allowing the internal
clock to be software calibrated to a tighter tolerance of ±10%,
using the CS pin and a reference time pulse provided by the
microcontroller.
Calibration of the internal clock is initiated by writing a
logic [1] to PE3. The calibration pulse, which must be 8.0 µs
for an internal clock speed of 1.0 MHz, will be sent on the CS
pin immediately after the SPI word is sent. No other SPI lines
will be toggled. A clock calibration will be allowed only if the
gauges are disabled or the pointers are not moving, as
indicated by status bits MOV0 and MOV1. Additional details
are provided in the Internal Clock Calibration section,
beginning on page 30.
Some applications may require a guaranteed maximum
pointer velocity and acceleration. Guaranteeing these
maximums requires that the nominal internal clock frequency
fall below 1.0 MHz. The frequency range of the calibrated
clock will always be below 1.0 MHz if bit PE4 is logic [0] when
initiating a calibration command, followed by an 8.0 µs
reference pulse. The frequency will be centered at 1.0 MHz if
bit PE4 is logic [1].
Some applications may require a slower calibrated clock
due to a lower motor gear reduction ratio. Writing a logic [1]
to bit PE2 will slow the internal oscillator by one-third. Slowing
the clock accommodates a longer calibration pulse without
overrunning the internal counter—a condition designed to
generate a CAL fault indication. For example, calibration for
a clock frequency of 667 kHz would require a calibration
pulse of 12 µs. Unless the internal oscillator is slowed by
writing PE2 to logic [1], a 12 µs calibration pulse may overrun
the counter and generate a CAL fault indication.
Some applications may require faster pointer positioning
than is provided with the air core motor emulation feature.
Writing logic [1] to bit PE5 will disable the air core emulation
for both gauges and provide an acceleration and deceleration
at the maximum that the velocity position ramp can provide.
If the Hold Counts need to be enabled and disabled
dynamically, then the POSxR commands could also be used.
Bit PE6 must always be written as a logic [0] during all
PECCR writes if the device is being used to drive an MMT
style motor. Similarly, this bit must always be written as a
logic [1] when being used to control Switec style motors.
The default Pointer Position 0 (PE7 = 0) will be the farthest
counter-clockwise position. A logic [1] written to bit PE7 will
change the location of the position 0, for the gauge selected
by bit PE8, to the farthest clockwise position. A change in
position 0 of only one, or both, of the two coils can be
accomplished by using bits PE8 and PE7. Performing an RTZ
will always move the pointer to position 0. Exercise care
when writing to PECCR bits PE8 and PE7 in order to prevent
accidental changes of the position 0 locations.
Bits PE11:PE8 determine the content of the bits clocked
out of the SO pin. When bit PE11 is at logic [0], the clocked
out bits will provide device status. If a logic [1] is written to bit
PE11, the bits clocked out of the SO pin, depending upon the
state of bits PE10:PE8, provides either:
• Accumulator information and detection status during
the RTZ (PE10 logic [0])
• Real time pointer position location at the time CS goes
low (PE10 logic [1] and PE9 logic [0]), or
• The real time step position of the pointer as described
in the velocity Table 30, page 28 (PE10, PE9, and PE8
logic [1]).
Additional details are provided in the SO Communication
section beginning on page 21.
If bit PE12 is logic [1] during a PECCR command, the state
of PE11:PE0 is ignored. This is referred to as the null
command and can be used to read device status without
affecting device operation.
Table 7. Power, Enable, Calibration, and Configuration Register (PECCR)
Address 000
Bits
D12
D11
D10
D9
D8
D7
D6
D5
D4
D3
D2
D1
D0
Read
–
–
–
–
–
–
–
–
–
–
–
–
–
Write
PE12
PE11
PE10
PE9
PE8
PE7
PE6
PE5
PE4
PE3
PE2
PE1
PE0
The bits in Table 7 are write-only.
PE12 (D12) — Null Command for Status Read
• 0 = Disable
• 1 = Enable
33976
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Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
PE11 (D11) — Status Select bit. This bit selects the
information clocked out of the SO pin.
• 0 = Device Status (the logic states of PE10, PE9, and
PE8 don’t cares)
• 1 = RTZ Accumulator Value, Gauge 0 or 1 Pointer
position, or Gauge 0 and 1 Velocity ramp position
(depending upon the logic states of PE10, PE9, and
PE8)
PE10 (D10) — RTZ Accumulator or Pointer Status Select
bit. This bit is recognized only when PE11 = 1.
• 0 = RTZ Accumulator Value and status
• 1 = Pointer Position or Speed
PE9 (D9) — Pointer Position or Pointer Speed Select bit.
This bit is recognized only if PE11 and PE10 = 1.
• 0 = Gauge 0 or Gauge 1 Pointer Position
• 1 = Gauge 0 and Gauge 1 Pointer Speed
PE8 (D8) — Pointer Position Gauge Select bit. Also the
Position 0 of the selected gauge is determined by the PE7
selection. This bit is recognized only if PE11 and PE10 = 1
and PE9 = 0.
• 0 = Gauge 0 position
• 1 = Gauge 1 position
PE7 (D7) — Position 0 Location Select bit. This bit
determines the Position 0 of the gauge selected by PE8. RTZ
direction will always be to the position 0.
• 0 = Position 0 is the most CCW (counterclockwise)
position
• 1 = Position 0 is the most CW (clockwise) position
PE6 (D6) — Motor Type Selection bit.
• 0 = MMT Style (coil phase difference = 90°)
• 1 = Switec Style (coil phase difference = 60°)
PE5 (D5) — Air Core Motor Emulation bit. This bit is
enabled or disabled (acceleration and deceleration is
constant if disabled).
• 0 = Enable
• 1 = Disable
PE4 (D4) — Clock Calibration Frequency Selector
• 0 = Maximum f =1.0 MHz (for 8.0 µs calibration pulse)
• 1 = Nominal f =1.0 MHz (for 8.0 µs calibration pulse)
PE3 (D3) — Clock Calibration Enable bit. This bit enables
or disables the clock calibration.
• 0 = Disable
• 1 = Enable
PE2 (D2) — Oscillator Adjustment
• 0 = tCLU
• 1 = 0.66 x tCLU
PE1 (D1) — Gauge 1 Enable bit. This bit enables or
disables the output driver of Gauge 1.
• 0 = Disable
• 1 = Enable
PE0 (D0) — Gauge 0 Enable bit. This bit enables or
disables the output driver of Gauge 0.
• 0 = Disable
• 1 = Enable
Address 001 — Maximum Velocity Register (VELR)
The Gauge Maximum Velocity Register is used to set a
maximum velocity for each gauge (refer to Table 8). Bits
V7:V0 contain a position value from 1– 225 that is
representative of the velocity position value described in
Table 30, Velocity Table, page 28. The table value becomes
the maximum velocity until it is changed to another value. If a
maximum value is chosen greater than the maximum velocity
in the acceleration table, the maximum table value becomes
the maximum velocity. If the motor is turning at a speed
greater than the new maximum, the motor immediately
moves down the velocity ramp until the speed falls equal to
or below it. Velocity for each motor can be changed
simultaneously or independently by writing V8 and/or V9 to a
logic [1]. Bits V12:V10 must be at logic [0] for valid VELR
commands.
Table 8. Maximum Velocity Register (VELR)
Address 001
Bits
D12
D11
D10
D9
D8
D7
D6
D5
D4
D3
D2
D1
D0
Read
–
–
–
–
–
–
–
–
–
–
–
–
–
Write
0
0
0
V9
V8
V7
V6
V5
V4
V3
V2
V1
V0
The bits in Table 8 are write-only.
V12:V10 (D12:D10) — These bits must be transmitted as
logic [0] for valid VELR commands
V9 (D9) — Gauge 1 Velocity. Specifies whether the
maximum velocity determined in the V7: V0 field will apply to
Gauge 1.
• 0 = Velocity does not apply to Gauge 1
• 1 = Velocity applies to Gauge 1
V8 (D8) — Gauge 0 Velocity. Specifies whether the
maximum velocity specified in the V7: V0 field will apply to
Gauge 0.
• 0 = Velocity does not apply to Gauge 0
• 1 = Velocity applies to Gauge 0
V7:V0 (D7:D0) — Maximum Velocity. Specifies the
maximum velocity position from Table 30, page 28. This
velocity will remain the maximum of the intended gauge until
33976
Analog Integrated Circuit Device Data
Freescale Semiconductor
15
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
changed by command. Velocities can range from position 1
(00000001) to position 225 (11111111).
Addresses 010 and 011 — Gauge 0/1 Position Registers
(POS0R, POS1R)
SI Address 010 (Gauge 0 Position Register) and SI
Address 011 (Gauge 1 Position Register) Register bits PO
11: PO0 are written to when communicating the desired
pointer positions.
Commanded positions can range from 0 to 4095. The D12
bit is used to disable the damping (i.e., hold counts) for each
respective gauge. This feature allows the user to easily turn
on and off the damping that was configured with the
RMPSELR. Disabling the hold counts allows the pointer to
decelerate to the commanded position, as fast as possible
down the velocity ramp. When disabled, the acceleration and
deceleration of the pointer are symmetrical.
Table 9. Gauge 0 Position Register (POS0R)
Address 010
Bits
D12
D11
D10
D9
D8
D7
D6
D5
D4
D3
D2
D1
D0
Read
–
–
–
–
–
–
–
–
–
–
–
–
–
Write
HE012
P0 11
P0 10
P0 9
P0 8
P0 7
P0 6
P0 5
P0 4
P0 3
P02
P01
P0 0
The bits in Table 9 are write-only.
HE0 12 (D12) — This bit is used to disable the damping
(i.e., hold counts) for Gauge 0 (1 = Damping disabled;
0 = Damping enabled).
P0 11:P0 0 (D11:D0) — Desired pointer position of
Gauge 0. Pointer positions can range from 0
(000000000000) to position 4095 (111111111111). For a
step motor requiring 12 microsteps per degree of pointer
movement, the maximum pointer sweep is 341.25°.
.
Table 10. Gauge 1 Position Register (POS1R)
Address 011
Bits
D12
D11
D10
D9
D8
D7
D6
D5
D4
D3
D2
D1
D0
Read
–
–
–
–
–
–
–
–
–
–
–
–
–
Write
HE112
P1 11
P1 10
P1 9
P1 8
P1 7
P1 6
P1 5
P1 4
P1 3
P1 2
P1 1
P1 0
The bits in Table 10 are write-only.
HE1 12 (D12) — This bit is used to disable the damping
(i.e., hold counts) for Gauge 1 (1 = Damping disabled;
0 = Damping enabled).
P1 11:P1 0 (D11:D0) — Desired pointer position of
Gauge 1. Pointer positions can range from 0
(000000000000) to position 4095 (111111111111). For a
step motor requiring 12 microsteps per degree of pointer
movement, the maximum pointer sweep is 341.25°
(4095 ÷ 12).
Address 100 — Gauge Return to Zero Register (RTZR)
Gauge Return to Zero Register (RTZR) (refer to Table 11,
page 17) is written to return the gauge pointers to the zero
position. During an RTZ event, the pointer is returned to zero
using full steps, where only one coil is driven at any point in
time. The back electromotive force (EMF) signal present on
the non-driven coil is integrated and its results are stored in
an accumulator.
A logic [1] written to bit RZ1 enables a Return to Zero for
Gauge 0 if RZ0 is logic [0], and Gauge 1 if RZ0 is logic [1],
respectively. Similarly, a logic [0] written to bit RZ1 disables a
Return to Zero for Gauge 0 when RZ0 is logic [0], and
Gauge 1 when RZ0 is logic [1], respectively.
Bits D12:D5 and D3:D2 must be at logic [0] for valid RTZR
commands.
Bit RZ4 is used to enable an unconditional RTZ event. A
logic [0] results in a typical RTZ event, automatically
providing a Stop when a stall condition is detected. A logic [1]
will result in RTZ movement, causing a Stop if a logic [0] is
written to bit RZ0. This feature is useful during development
and characterization of RTZ requirements.
33976
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Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
Table 11. Return to Zero Register (RTZR)
Address 100
Bits
D12
D11
D10
D9
D8
D7
D6
D5
D4
D3
D2
D1
D0
Read
–
–
–
–
–
–
–
–
–
–
–
–
–
Write
0
0
0
0
0
0
0
0
RZ4
0
RZ2
RZ1
RZ0
The register bits in Table 11 are write-only.
RZ12:RZ5 (D12:D5) — These bits must be transmitted as
logic [0] for valid commands.
RZ4 (D4) — This bit is used to enable an unconditional
RTZ event.
• 0 = Automatic Return to Zero
• 1 = Unconditional Return to Zero
RZ3 (D3) — This bit must be transmitted as logic [0] for
valid commands.
RZ2 (D2) — Return to Zero Direction bit. This bit is used to
properly sequence the integrator, depending upon the
desired zeroing direction.
• 0 = Return to Zero will occur in the CCW direction
(PE7 = 0)
• 1 = Return to Zero will occur in the CW direction
(PE7 = 1)
RZ1 (D1) — Return to Zero Direction. This bit commands
the selected gauge to return the pointer to zero position.
• 0 = Return to Zero Disabled
• 1 = Return to Zero Enabled
RZ0 (D0) — Gauge Select: Gauge 0/Gauge 1. This bit
selects the gauge to be commanded.
• 0 = Selects Gauge 0
• 1 = Selects Gauge 1
Address 101 — Gauge Return to Zero Configuration
Register
Gauge Return to Zero Configuration Register (RTZCR) is
used to configure the Return to Zero Event (refer to Table 12,
page 18). It is written to modify (1) the step time, or rate at
which the pointer moves during an RTZ event, (2) the
integration blanking time, which is the time immediately
following the transition of a coil from a driven state to an open
state in the RTZ mode, and (3) the threshold of the RTZ
integration register.
The values used for this register should be selected during
development to optimize the RTZ for each application.
Selecting an RTZ step rate resulting in consistently
successful zero detections depends on a clear understanding
of the motor characteristics. Specifically, resonant
frequencies exist due to the interaction between the motor
and the pointer. This command allows movement of the RTZ
pointer speed away from these frequencies. Also, some
motors require a significant amount of time for the pointer to
settle to a steady state position when moving from one full
step position to the next. Consistent and accurate integration
values require the pointer be stationary at the end of the full
step time.
Bits RC3:RC0, RC12:RC11, and RC4 determine the time
spent at each full step during an RTZ event. Bits RC3:RC0
are used to select a ∆t ranging from 0 ms (0000) to 61.44 ms
(1111) in increments of 4.096 ms (refer to Table 13,
page 18). The ∆t is multiplied by the factor M, which is
defined by bits RC12:RC11. The product is then added to the
blanking time, selected using bit RC4, to generate the full
step time. The multiplier selected with RC12:RC11 will be
1 (00), 2 (01), or 4 (10) as illustrated in the equations below.
The multiplier selected with RC12:RC11 will be 1 (00), 2 (01),
or 4 (10) as illustrated in the equations below. Note that the
RC12:RC11 value of 8 (11) is not recommended for use in a
product design application, because of the potential for an
RTZ accumulator internal overflow, due to the long time step.
The blanking time that is selected with bit RC4 determines
the time that is provided immediately following a full step
change, before enabling the integration of the non-driven coil
signal. The blanking time is either 512 µs when RC4 is logic
[0], or 768 µs when it is logic [1].The full step time is
generated using the following equations:
When D3:D0 (RC3:RC0) ≠ 0000
Full Step (t) = ∆t x M + blanking (t) (1)
When D3:D0 (RC3:RC0) = 0000
Full Step (t) = blanking (t) + 2.048 ms (2)
Note In equation (2), a 2.048 ms offset is added to the full
step time when the RC3:RC0 = 0000. The full step time
default value after a logic reset is 12.80 ms
(RC12:RC11 = 00, RC4 = 0, and RC3:RC0 = 0011).
If there are two full steps per degree of pointer movement,
the pointer speed is 1/(FullStep x 2) deg/s.
Detecting pointer movement is accomplished by
integrating the EMF present in the non-driven coil during the
RTZ event. The integration circuitry is implemented using a
Sigma-Delta converter resulting in the placement of a value
in the 15-bit RTZ accumulator at the end of each full step. The
value in the RTZ accumulator represents the change in flux
and is compared to a threshold. Values above the threshold
indicate a pointer is moving. Values below the threshold
indicate a stalled pointer, thereby resulting in the cessation of
the RTZ event.
The RTZ accumulator bits are signed and represented in
two’s complement. After a full step of integration, a sign bit of
33976
Analog Integrated Circuit Device Data
Freescale Semiconductor
17
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
0 is the indicator of an accumulator exceeding the decision
threshold of 0, and the pointer is assumed to still be moving.
Similarly, if the sign bit is logic [1] after a full step of
integration, the accumulator value is negative and the pointer
is assumed to be stopped. The integrator and accumulator
are initialized after each full step. If the PECCR command is
written to clock out the RTZ accumulator values via the SO,
the OD14 bit corresponds to the sign bit of the RTZ
accumulator.
Accurate pointer stall detection depends on a correctly
preloaded accumulator for specific gauge, pointer, and full
step combinations. Bits RC10:RC5 are used to offset the
initial RTZ accumulator value, properly detecting a stalled
motor. The initial accumulator value at the start of a full step
of integration is negative. If the accumulator was correctly
preloaded, a free-moving pointer will result in a positive value
at the end of the integration time, and a stalled pointer will
result in a negative value. The preloaded values associated
with each combination of bits RC10:RC5 are illustrated in
Table 14, page 19. The accumulator should be loaded with a
value resulting in an accumulator MSB to a logic [1] when the
motor is stalled. For the default mode, after a power-up or any
reset, the 33976 device sets the accumulator value to -1,
resulting in an unconditional RTZ pointer movement until it is
increased.
.
Table 12. RTZCR SI Register Assignment
Address 101
Bits
D12
D11
D10
D9
D8
D7
D6
D5
D4
D3
D2
D1
D0
Read
–
–
–
–
–
–
–
–
–
–
–
–
–
Write
RC12
RC11
RC10
RC9
RC8
RC7
RC6
RC5
RC4
RC3
RC2
RC1
RC0
The bits in Table 12 are write-only.
RC12:RC11 (D12:D11) — These bits, along with RC3:RC0
(D3:D0) and RC4 (D4), determine the full step time and,
therefore, the rate at which the pointer will move during an
RTZ event. The values of D12:D11 determine the multiplier
(M) used in equation (1) (refer to page 17).
RC12:RC11 = M; default value = 00
• 00 = 1
• 01 = 2
• 10 = 4
• 11 = 8 (Not to be used for design)
RC10:RC5 (D10:D5) — These bits determine the value
preloaded into the RTZ integration accumulator to adjust the
detection threshold. Values range from -1 (00000000) to 1009 (11111111) as shown in Table 14, the default value =
000000.
RC4 (D4) — This bit determines the RTZ blanking time
(blanking (t)). The default value = 0
• 0 = 512 µs
• 1 = 768 µs
RC3:RC0 (D3:D0) — These bits, along with RC12:RC11
(D12:D11) and RC4 (D4), determine the time variables used
to calculate the full step times with equations (1) or (2)
illustrated above. RC3:RC0 determines the ∆t time. The ∆t
values range from 0 (0000) to 61.440 ms (1111) and are
shown in Table 13. The default ∆t is 0 (0011).
Note Equation (2) (refer to page 17) is only used to
calculate the full step time if RC3:RC0 = 0000. Use
equation (1) for all other combinations of RC3:RC0.
Table 13. RTZCR Full Step Time
RC3
RC2
RC1
RC0
∆t (ms)
0
0
0
0
0
0
0
0
1
4.096
0
0
1
0
8.192
0
0
1
1
12.288
0
1
0
0
16.384
0
1
0
1
20.480
0
1
1
0
24.576
0
1
1
1
28.672
1
0
0
0
32.768
1
0
0
1
36.864
1
0
1
0
40.960
1
0
1
1
45.056
1
1
0
0
49.152
1
1
0
1
53.248
1
1
1
0
57.344
1
1
1
1
61.440
33976
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Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
Table 14. RTZCR Accumulator Offset
RC10
RC9
RC8
RC7
RC6
RC5
Preload Value
(PV)
Initial Accumulator
Value = (-16 x PV) -1
0
0
0
0
0
0
0
-1
0
0
0
0
0
1
1
-17
0
0
0
0
1
0
2
-33
0
0
0
0
1
1
3
-49
0
0
0
1
0
0
4
-65
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
1
1
1
1
1
1
63
-1009
Address 110 — Ramp Selection Register (RMPSELR)
SI Address 110 Ramp Selection Register (RMPSELR)
(refer to Table 15, page 20). A write to the 33976 using this
register allows the master to independently modify the
pointer movement response characteristics of each gauge
driver. The user has three variables that can be configured,
during the initialization of the device, to provide quick and
responsive pointers (e.g., tachometer applications) or soft
landing and less responsive pointers (e.g., speedometer or
fuel indicators). These three variables are (1) the ramp zero
selection RS (RS3:RS0), (2) the hold count cut-in location
offset variable HCP (HCP2: HCP0), and (3) the hold count
value HC, (HC3:HC0). Each of these variables is described
below and an implementation example is shown in Figure 11,
page 31.
The state machine uses the velocity ramp (refer to
Table 30, page 28) to control the acceleration, deceleration
and speed of the pointer movement. During an acceleration
from a stopped position, the state machine will microstep the
pointer at each velocity step, starting with step 0, in
succession until the desired pointer speed is reached.
Similarly, as the pointer approaches the commanded
position, the state machine will microstep the motor at
successive velocity steps down the velocity ramp until
reaching step 0. The fastest that a pointer can accelerate,
decelerate or change directions is limited by the velocity
ramp.
For example, if a pointer is moving in the clockwise
direction and is commanded to a position that is counter
clockwise from the current pointer location, then the state
machine must first decelerate the pointer down the ramp to
the step 0 location, change directions and then accelerate up
the ramp towards the commanded location. In this situation,
the state machine will force movement down and then up the
ramp as fast as possible by stepping at each Velocity Position
only once for a direction change. The low velocity steps (e.g.,
Velocity Position 1 is 27 ms) are significant in that they can
limit the speed with which a pointer can change direction.
Bits RS3:RS0 of the RMPSELR are used to truncate as
many as 15 velocity steps off of the bottom of the velocity
ramp. The value of RS determines the Initial Velocity Ramp
Position:
Initial Velocity Position = RS + 1
For example, writing a value of 4 to these bits truncates the
velocity ramp by 4 and would result in a first and last velocity
step of 5.86ms (Velocity Position 5). A pointer will change
directions much faster with this abbreviated ramp than it
would if using the default ramp with a Velocity Position 1 of
27 ms
Most applications require a smooth dynamic pointer as the
commanded position is constantly updated. Movement along
the ramp at the maximum acceleration and deceleration (only
one step at each velocity position) results in a choppy
movement because the movement velocity range is large for
small changes in position as the pointer quickly reaches
commanded locations from command to command.
Configuring the state machine to repeat velocity steps at
several of the last few step locations, when the pointer
decelerates to the commanded location, can eliminate this
choppy movement. These repetitive steps are referred to as
hold counts.
Bits HCP2: HCP0 of the RMPSELR determine the velocity
step location at which the hold counts begin during a
deceleration to the commanded position. The value written to
HCP2: HCP0 (HCP) is multiplied by 8 and added to the RS
value. The result is the first velocity position, or the Hold
Count Cut-In Point, to which the hold counts will apply during
a deceleration.
First Velocity Position w/ Hold Counts = HCP x 8 + RS
The exception to this is when the HCP2: HCP0 value is
000. In this case, HCP = 8 and the cut-in point will be 64 steps
above the RS value. The default value of the HCP = 2 or a
hold count cut-in point of 16 velocity steps above the RS
value.
33976
Analog Integrated Circuit Device Data
Freescale Semiconductor
19
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
The value of RS also determines the last velocity position
step for which the Hold Counts are applied:
Last Velocity Position w/ Hold Counts = RS + 2
The number of hold counts per applicable velocity step is
determined by the value written to HC3:HC0 (HC) and can
range from 0 to 15 steps. This number of hold counts will be
applied to each step below the Hold Count Cut-In as
determined by HCP and RS. The default value of HC is 5.
Note: the following relationship between the variables
must be adhered to for the state machine to work properly:
HC x (HCP x 8 - 1) + (225 - RS) < 512
Therefore, if RS = 0 and the Hold Count Cut-In point is 64,
the largest value of Hold Counts you can choose is 4.
4 * (64 - 1) + (225 - 0) = 477
The GSEL bit determines which of the two gauges the rest
of the RMPSELR bits are applied to. A GSEL bit set to logic
1 will apply the RMPSELR data to Gauge 1 and, Logic 0 to
Gauge 0, respectively. Configuring both gauges requires two
writes to this register.
Table 15. Ramp Selection Register (RMPSELR)
Address 101
Bits
D12
D11
D10
D9
D8
D7
D6
D5
D4
D3
D2
D1
D0
Read
–
–
–
–
–
–
–
–
–
–
–
–
–
HCP2
HCP1
HCP0
HC3
HC2
HC1
HC0
RS3
RS2
RS1
RS0
Write
GSEL 12 GSEL 11
The bits in Table 15 are write-only.
GSEL 12 (D12) — Gauge Select bit. The value of this bit
determines the gauge for which the settings apply (refer to
page 17):
• 1 = Gauge 1
• 0 = Gauge 0
GSEL 11 (D11) — This bit must be transmitted as Logic 0
for valid commands.
HCP2 : HPC0 (D10 : D8) — Hold Count Cut-in Point
variable. These bits determine HCP, which is then multiplied
by 8, and added to the RS number, to determine the actual
Hold Count Cut-In Step value. The values of HCP range from
1 to 8 as shown in Table 16. The default value is 2.
.
Table 16. First Hold Count Velocity Position
Table 17. Hold Counts Per Step
HC3
HC2
HC1
HC0
Hold Counts /
Step (HC)
0
0
0
0
0
0
0
0
1
1
0
0
1
0
2
0
0
1
1
3
0
1
0
0
4
0
1
0
1
5
0
1
1
0
6
0
1
1
1
7
HCP2
HCP1
HCP0
Velocity Step
(HCP x 8 + RS)
0
0
0
64 + RS
1
0
0
0
8
0
0
1
8 + RS
1
0
0
1
9
0
1
0
16 + RS
1
0
1
0
10
0
1
1
24 + RS
1
0
1
1
11
1
0
0
32 + RS
1
1
0
0
12
1
0
1
40 + RS
1
1
0
1
13
1
1
0
48 + RS
1
1
1
0
14
1
1
1
56 + RS
1
1
1
1
15
HC3 : HC0 (D7 : D4) — These bits determine the number of
Hold Counts that will be applied to the steps that are
determined by the HCP2:HCP0 and RS3:RS0 bits. The HC
values range from 0 to 15 and are shown in Table 17. The
default value is 5.
RS3 : RS0 (D3 : D0) — These bits determine the number of
velocity steps that are truncated from the Velocity Position
ramp. The values range from 0 to 15 and are shown in
Table 18. The default value is 0.
33976
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Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
Output register is selected and it is clocked out via the SO. If
the message length was determined to be invalid, the fault
information will not be cleared and will be transmitted again
during the next valid SPI message. Pointer status information
bits (e.g., pointer position, velocity, and commanded position
status) will always reflect the real time state of the pointer.
Any bits clocked out of the SO pin after the first 16 are
representative of the initial message bits clocked into the SI
pin since the CS pin first transitioned to a logic [0]. This
feature is useful for daisy-chaining devices as well as
message verification.
As described above, the last valid write to bits PE11:PE8
of the PECCR command determines the nature of the status
data that is clocked out of the SO pin.
There are five different types of status information
available:
Table 18. Truncated Velocity Steps
RS3
RS2
RS1
RS0
Zero Velocity
Position # (RS)
0
0
0
0
0
0
0
0
1
1
0
0
1
0
2
0
0
1
1
3
0
1
0
0
4
0
1
0
1
5
0
1
1
0
6
0
1
1
1
7
1
0
0
0
8
2. RTZ Accumulator Status (refer to Table 22, page 23)
1
0
0
1
9
1
0
1
0
10
3. Gauge 0 Pointer Position Status (refer to Table 24,
page 24)
1
0
1
1
11
1
1
0
0
12
1
1
0
1
13
1
1
1
0
14
1
1
1
1
15
1. Device Status (refer to Table 20, page 21)
4. Gauge 1 Pointer Position Status (refer to Table 26,
page 24)
5. Gauge 1 and 2 Pointer Velocity Status (refer to
Table 28, page 24)
Once a specific status type is selected, it will not change
until either the PECCR command bits PE11:PE8 (D11:D8)
are written to select another or the device is reset. Each of the
Status types and the PECCR bit necessary to select them are
described in the following paragraphs.
SO Communication
Device Status Information
When the CS pin is pulled low, the internal status register,
as configured with the PECCR command bits PE11:PE8, is
loaded into the output register and the data is clocked out
MSB (OD15) first. Following a CS transition 0 to 1, the device
determines if the shifted-in message was of a valid length (a
valid message length is one that is greater than 0 bits and a
multiple of 16 bits) and, if so, latches the incoming data into
the appropriate registers.
At this time, the SO pin is tri-stated and the status register
is now able to accept new status information. Fault status
information will be latched and held until the Device Status
Most recent valid PECCR command resulting in the
Device Status output:
Table 19.
D11
D10
D9
D8
0
x
x
x
x = Don’t care.
Table 20. Device Status Output Register
Bits
OD15
OD14
Read
DIR1
DIR0 0POS1 0POS0 CMD1 CMD0
Write
–
–
OD13
–
OD12
OD11
–
–
OD10
–
OD9
OD8
OD7
OV
UV
CAL
–
–
–
OD6
OD5
OD4
OVUV MOV1 MOV0
–
–
–
OD3
OD2
OD1
OD0
RTZ1
RTZ0
OT1
OT0
–
–
–
–
The bits in Table 20 are read-only bits.
DIR1 (OD15) — This bit indicates the direction Gauge 1
pointer is moving.
• 0 = Toward position 0
• 1 = Away from position 0
DIR0 (OD14) — This bit indicates the direction Gauge 0
pointer is moving.
• 0 = Toward position 0
• 1 = Away from position 0
33976
Analog Integrated Circuit Device Data
Freescale Semiconductor
21
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
0POS1 (OD13) — This bit indicates the configured Position
0 for Gauge 1.
•0 = Farthest CCW
•1 = Farthest CW
0POS0 (OD12) — This bit indicates the configured Position
0 for Gauge 0.
• 0 = Farthest CCW
• 1 = Farthest CW
CMD1 (OD11) — This bit indicates whether Gauge 1 is at
the most recently commanded position.
• 0 = At commanded position
• 1 = Not at commanded position
CMD0 (OD10) — This bit indicates whether Gauge 0 is at
the most recently commanded position.
• 0 = At commanded position
• 1 = Not at commanded position
OV (OD9) — Overvoltage Indication. A logic [1] on this bit
indicates VPWR voltage exceeded the upper limit of VPWROV
since the last SPI communication (refer to the Static Electrical
Characteristics table under POWER INPUT, page 5). An
overvoltage event will automatically disable the driver
outputs. Because the pointer may not be in the expected
position, the master may want to re-calibrate the pointer
position with an RTZ command after the voltage returns to a
normal level. For an overvoltage event, both gauges must be
re-enabled as quickly as this flag returns to logic [0]. The
state machine will continue to operate properly as long as
VDD is within the normal range.
• 0 = Normal range
• 1 = Battery voltage exceeded VPWROV
UV (OD8) — Undervoltage Indication. A logic [1] on this bit
indicates the VPWR voltage fell below VPWRUV since the last
SPI communication (refer to the Static Electrical
Characteristics table under POWER INPUT, page 5). An
undervoltage event is just flagged; however, at some voltage
level below 4.0 V, the outputs turn OFF and the state
machine resets. Because the pointer may not be in the
expected position, the master may want to re-calibrate the
pointer position with an RTZ command after the voltage
returns to a normal level. For an undervoltage event, both
gauges may need to be re-enabled as quickly as this flag
returns to logic [0]. The state machine will continue to operate
properly as long as VDD is within the normal range.
• 0 = Normal range
• 1 = Battery voltage fell below VPWRUV
CAL (OD7) — Calibrated Clock out of Specification. A
logic [1] on this bit indicates the clock count calibrated to a
value outside the expected range given the tolerance
specified by tCLC in the Dynamic Electrical Characteristics
table under POWER OUTPUT AND CLOCK TIMINGS,
page 7.
• 0 = Clock within spec
• 1 = Clock out of spec
OVUV (OD6) — Undervoltage or Overvoltage Indication.
A logic [1] on this bit indicates the VPWR voltage fell to a level
below the VPWRUV since the last SPI communication (refer to
the Static Electrical Characteristics table under POWER
INPUT, page 5). An undervoltage event is just flagged, while
an overvoltage event automatically disables the drive
outputs. Because the pointer may not be in the expected
position, the master may want to re-calibrate the pointer with
an RTZ command after the voltage returns to normal level.
For an overvoltage event, both gauges must be re-enabled
as soon as this flag returns to logic [0]. The state machine will
continue to operate properly as long as VDD is within the
normal range.
• 0 = Normal range
• 1 = Battery voltage fell below VPWRUV or exceeded
VPWROV
MOV1 (OD5) — This bit identifies Gauge 1 movement
since last SPI communication. A logic [1] on this bit indicates
the Gauge 1 pointer position changed since the last SPI
command. This information allows the master to confirm the
pointer is moving as commanded. This bit may also be used
to determine if Gauge 1 is enabled or disabled.
• 0 = Gauge 1 position has not changed since the last SPI
command
• 1 = Gauge 1 pointer position has changed since the last
SPI command
MOV0 (OD4) — Gauge 0 Movement Since last SPI
Communication. A logic [1] on this bit indicates the Gauge 0
pointer position has changed since the last SPI command.
This information allows the master to confirm the pointer is
moving as commanded. This bit may also be used to
determine if Gauge 0 is enabled or disabled.
• 0 = Gauge 0 position has not changed since the last SPI
command
• 1 = Gauge 0 pointer position has changed since the last
SPI command
RTZ1 (OD3) — RTZ1 Is Enabled or Disabled. A logic [1]
on this bit indicates Gauge 1 is in the process of returning to
the zero position as requested with the RTZ command. This
bit will continue to indicate a logic [1] until the SPI message
following a detection of the zero position, or the RTZ feature
is commanded OFF using the RTZ message.
• 0 = Return to Zero disabled
• 1 = Return to Zero enabled successfully
RTZ0 (OD2) — RTZ0 Is Enabled or Disabled. A logic [1]
on this bit indicates Gauge 0 is in the process of returning to
the zero position as requested with the RTZ command. This
bit continues to indicate a logic [1] until the SPI message
following a detection of the zero position, or the RTZ feature
is commanded OFF using the RTZ message.
• 0 = Return to Zero disabled
• 1 = Return to Zero enabled successfully
OT1 (OD1) — Gauge 1 Junction Overtemperature.
A logic [1] on this bit indicates that the coil drive circuitry
dedicated to drive Gauge 1 has exceeded the maximum
allowable junction temperature since the last SPI
communication and that Gauge 1 has been disabled. It is
recommended that the pointer be re-calibrated using the RTZ
33976
22
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
command after re-enabling the gauge using the PECCR
command. This bit remains logic [1] until the gauge is
enabled.
• 0 = Temperature within range
• 1 = Gauge 1 maximum allowable junction temperature
condition has been reached
OT0 (OD0) — Gauge 0 Junction Overtemperature. A
logic [1] on this bit indicates that the coil drive circuitry
dedicated to drive Gauge 0 has exceeded the maximum
allowable junction temperature since the last SPI
communication and that Gauge 0 has been disabled. It is
recommended that the pointer be re-calibrated using the RTZ
command after re-enabling the gauge using the PECCR
command. This bit remains logic [1] until the gauge is reenabled.
•0 = Temperature within range1 = Gauge 0 maximum
allowable junction temperature condition is reached
RTZ Accumulator Status Information
Most recent valid PECCR command resulting in the RTZ
Accumulator status output:
Table 21.
D11
D10
D9
D8
1
0
x
x
x = Don’t care.
Table 22. RTZ Accumulator Status Output Register
Bits
OD15
Read
RTZ
Write
–
OD14
OD13
OD12
OD11
OD10
OD9
ACC14 ACC13 ACC12 ACC11 ACC10 ACC9
–
–
–
–
–
–
OD8
OD7
OD6
OD5
OD4
OD3
OD2
OD1
OD0
ACC8
ACC7
ACC6
ACC5
ACC4
ACC3
AC2C
ACC1
ACC0
–
–
–
–
–
–
–
–
–
The bits in Table 22 are read-only bits.
RTZ (OD15) — RTZ Bit Is Enabled or Disabled. A logic [1]
on this bit indicates that the Gauge is in the process of
returning to the zero position as requested with the RTZ
command. This bit will continue to indicate a logic [1] until the
SPI message following a detection of the zero position, or the
RTZ feature is commanded OFF using the RTZ message.
• 0 = Return to Zero disabled
• 1 = Return to Zero enabled successfully
ACC14:ACC0 (OD14:OD0) — These 15 bits are from the
RTZ accumulator. They represent the integrated signal
present on the non-driven coil during an RTZ event. These
bits are logic [0] after power-on reset, or after the RST pin
transitions from logic [0] to [1]. After an RTZ event, they will
represent the last RTZ accumulator result before the RTZ
was stopped. ACC14 is the MSB and is the sign bit used for
zero detection. Negative numbers have MSB logic [1] and
are coded in two’s complement.
Figure 8. RTZ Accumulator (Typical)
The analog-to-digital converter's linear input range covers
the expected magnitude of motor back e.m.f. signals, which
is usually less than 500mV. Input signals greater than this will
not cause any damage (the circuit is connected to the motor
H-Bridge drivers, and thus is exposed to the full magnitude of
the drive voltages), but may cause some small loss of
linearity. A typical plot of output vs. input is shown in Figure 8
for 4ms step times.
Gauge 0 Pointer Position Status Information
Most recent valid PECCR command resulting in the
Gauge 0 Pointer Position status output:
Table 23.
D11
D10
D9
D8
1
1
0
0
33976
Analog Integrated Circuit Device Data
Freescale Semiconductor
23
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
Table 24. Gauge 0 Pointer Position Status Output Register
Bits
OD15
OD14
OD13
Read
ENB0
DIR0
DIRC0 CMD0 POS11 POS10 POS9
Write
–
–
–
OD12
–
OD11
–
OD10
–
OD9
–
OD8
OD7
OD6
OD5
OD4
OD3
OD2
OD1
OD0
POS8
POS7
POS6
POS5
POS4
POS3
POS2
POS1
POS0
–
–
–
–
–
–
–
–
–
The bits in Table 24 are read-only bits.
ENB0 (OD15) — This bit indicates whether Gauge 0 is
enabled.
• 0 = Disabled
• 1 = Enabled
DIR0 (OD14) — This bit indicates the direction Gauge 0 is
moving.
• 0 = Toward position 0
• 1 = Away from position 0
CMD0 (OD12) — This bit indicates whether Gauge 0 is at
the most recently commanded position.
• 0 = At commanded position
• 1 = Not at commanded position
POS11:POS0 (OD11:OD0) — These 12 bits represent the
actual position of the pointer at the time CS transitions to a
logic [0].
Gauge 1 Pointer Position Status Information
DIRC0 (OD13) — This bit is used to determine whether the
direction of the most recent pointer movement is toward the
last commanded position or away from it.
• 0 = Direction of the pointer movement is toward the
commanded position
• 1 = Direction of the pointer movement is away from the
commanded position
Most recent valid PECCR command resulting in the
Gauge 1 Pointer Velocity status output:
Table 25.
D11
D10
D9
D8
1
1
0
1
Table 26. Gauge 1 Pointer Position Status Output Register
Bits
OD15
OD14
OD13
Read
ENB1
DIR1
DIRC1 CMD1 POS11 POS10 POS9
Write
–
–
–
OD12
–
OD11
–
OD10
–
OD9
–
OD8
OD7
OD6
OD5
OD4
OD3
OD2
OD1
OD0
POS8
POS7
POS6
POS5
POS4
POS3
POS2
POS1
POS0
–
–
–
–
–
–
–
–
–
The bits in Table 26 are read-only bits.
ENB1 (OD15) — This bit indicates if Gauge 1 is enabled.
• 0 = Disabled
• 1 = Enabled
DIR1 (OD14) — This bit indicates the direction Gauge 1
pointer is moving.
• 0 = Toward position 0
• 1 = Away from position 0
DIRC1 (OD13) — This bit determines if the direction of the
most recent pointer movement is toward, or away from, the
last commanded position.
• 0 = Direction of the pointer movement is toward the
commanded position
• 1 = Direction of the pointer movement is away from the
commanded position
CMD1 (OD12) — This bit indicates if Gauge 1 is at the most
recently commanded position.
• 0 = At commanded position
• 1 = Not at commanded position
POS11:POS0 (OD11:OD0) — These 12 bits represent the
actual position of the pointer at the time CS transitions to a
logic [0].
Gauge 0 and 1 Pointer Velocity Status Information
Most recent valid PECCR command resulting in the
Gauge 0 and 1 Pointer Velocity status output:
Table 27.
D11
D10
D9
D8
1
1
1
x
x = Don’t care.
33976
24
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
Table 28. Gauge 0 and 1 Pointer Velocity Status Output Register
Bits
OD15
OD14
OD13
OD12
OD11
OD10
OD9
OD8
OD7
OD6
OD5
OD4
OD3
OD21
OD1
OD0
Read
1V7
1V6
1V5
1V4
1V3
1V2
1V1
1V0
0V7
0V6
0V5
0V4
0V3
0V2
0V1
0V0
Write
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
The bits in Table 28 are read-only bits.
1V7:1V0 (OD15:OD8) — These 8 bits represent the step
table value that indicates the actual velocity step location
(refer to Table 30, page 28) of the Gauge 1 pointer at the
time that the CS transitions to a logic [0].
Note For both sets of bits,1V7:1V0 and 0V7:0V0, if the
ramp is truncated with the RMPSELR, the velocity position
step that will be read when the pointer is no longer moving will
be the velocity position that identifies it in the untruncated
ramp (e.g., if RS = 2, then the velocity step location will be 3
when the pointer is at the commanded position).
0V7:0V0 (OD7:OD0) — These 8 bits represent the step
table value that indicates the actual velocity step location
(refer to Table 30) of the Gauge 0 pointer at the time that the
CS transitions to a logic [0].
STATE MACHINE OPERATION
The two-phase step motor has maximum allowable
velocities and acceleration and deceleration.The purpose of
the step motor state machine is to drive the motor with
maximum performance while remaining within the motor’s
voltage, velocity, and acceleration constraints.
A requirement of the state machine is to ensure the
deceleration phase begins at the correct time and pointer
position. When commanded, the motor will accelerate
constantly to the maximum velocity, then move toward the
commanded position. Eventually, the pointer will reach the
calculated location where the movement has to decelerate,
slowing safely to a stop at the desired position. During the
deceleration phase, the motor will not exceed the maximum
deceleration.
During normal operation, both step motor rotors are
microstepped with 24 steps per electrical revolution (see
Figure 9). A complete electrical revolution results in two
degrees of pointer movement. There is a second (smaller)
state machine in the IC controlling these microsteps. This
state machine receives clockwise or counter-clockwise index
commands at intervals, stepping the motor in the appropriate
direction by adjusting the current in each coil. Normalized
values are provided in Table 29, page 26.
33976
Analog Integrated Circuit Device Data
Freescale Semiconductor
25
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
IMAX
+
SINx
0
ICOIL
IMAX
IMAX
+
ICOIL
COSx
0
IMAX
Clockwise Microsteps for PE6 = 0
IMAX
Imax
SINx
SINx
++
00
IICOIL
coil
_-
-
Imax
IMAX
0
1
2
3
4
5
6
7
8
9
10
11 12 13
14 15 16 17 18 19 20
21 22
23
Imax
IMAX
COSx
COS
x
++
IICOIL
coil
0
_IMAX
Imax
0
1
2
3
4
5
6
7
8
9
10 11 12 13 14
15
16 17 18 19 20 21 22 23
FIGURE
6b.Microsteps
CW MICROSTEPS
Clockwise
for PE6 = 1 for PE6=1
Figure 9. Clockwise Microsteps
Table 29. Coil Step Value
Table 29. Coil Step Value
COS (Angle)*
PE6 = 0
COS (Angle 30)*
PE6 = 1
Step
Angle
SINE
(Angle)*
0
0
0
1
0.866
1
15
0.259
0.965
0.966
2
30
0.5
0.866
1
3
45
0.707
0.707
0.966
4
60
0.866
0.5
0.866
5
75
0.966
0.259
0.707
6
90
1
0
0.500
7
105
0.966
-0.259
0.259
8
120
0.866
-0.5
0
9
135
0.707
-0.707
-0.259
10
150
0.5
-0.866
-0.500
11
165
0.259
-0.966
-0.707
12
180
0
-1
-0.866
13
195
-0.259
-0.966
-0.966
33976
26
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
Table 29. Coil Step Value
and solving for v in terms of u, s, and t gives:
2
/
v= t-u
The correct value of t to use in this equation is the
quantized value obtained above.
From these equations a set of recursive equations can be
generated to give the allowed time step between motor
indexes when the motor is accelerating from a stop to its
maximum velocity.
Starting from a position p of 0 and a velocity v of 0, these
equations define the time interval between steps at each
position. To drive the motor at maximum performance, index
commands are given to the motor at these intervals. A table
is generated giving the time step ∆t at an index position n.
14
210
-0.5
-0.867
-1
15
225
-0.707
-0.707
-0.966
16
240
-0.866
-0.5
-0.866
17
255
-0.966
-0.259
-0.707
18
270
-1
0
-0.500
19
285
-0.966
0.259
-0.259
20
300
-0.866
0.5
0
21
315
-0.707
0.707
0.259
22
330
-0.5
0.866
0.500
p0 = 0
23
345
-0.259
0.966
0.707
v0 = 0
* Denotes normalized values.
The motor is stepped by providing index commands at
intervals. The time between steps defines the motor velocity,
and the changing time defines the motor acceleration.
The state machine uses a table to define the allowed time
and also the maximum velocity. A useful side effect of the
table is that it also allows the direct determination of the
position at which the velocity should reduce to stop the motor
at the desired position.
The motor equations of motion are generated as follows.
(The units of position are steps, and velocity and acceleration
are in steps/second and steps/second².)
From an initial position of 0 with an initial velocity (u), the
motor position (s) at a time (t) is:
s = ut +
1
2
at
2
For unit steps, the time between steps is:
− u + u 2 + 2a
⇒t =
a
This defines the time increment between steps when the
motor is initially travelling at a velocity u. In the ROM, this time
is quantized to multiples of the system clock by rounding
upwards, ensuring acceleration never exceeds the allowed
value. The actual velocity and acceleration is calculated from
the time step actually used.
Using|
v2 = u2 + 2as
and
v = u + at
where
⎡ ⎤ indicates rounding up.
vn = 2
∆t n
− v n −1
Pn = n
Note Pn = n. This means on the n th step the motor has
indexed by n positions and has been accelerating steadily at
the maximum allowed rate. This is critical because it also
indicates the minimum distance the motor must travel while
decelerating to a stop. For example, the stopping distance is
also equal to the current value of n.
The algorithm to drive the motor is similar to:
1. While the motor is stopped, wait until a command is
received.
2. Send index pulses to the motor at an ever-increasing
rate, according to the time steps in Table 30 until:
a. The maximum velocity is reached, at which point
the time intervals stop decreasing, or
b. The distance remaining to travel is less than the
current index in the table. At this point, the stopping
distance is equal to the remaining distance, and to
ensure it will stop at the required position, the motor
must begin decelerating.
An example of the velocity table for a particular motor is
provided in Table 30. This motor’s maximum speed is
4800 microsteps/s (at 12 microsteps/degrees), and its
maximum acceleration is 54000 microsteps/s2. The table is
quantized to a 1.0 MHz clock.
33976
Analog Integrated Circuit Device Data
Freescale Semiconductor
27
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
Table 30. Velocity Table
Velocity
Position
Time
Between
Steps (µs)
Velocity
(µSteps/s)
Velocity
Position
Time
Between
Steps (µs)
Velocity
(µSteps/s)
Velocity
Position
Time
Between
Steps (µs)
Velocity
(µSteps/s)
0
0
0.00
76
380
2631.6
152
257
3891.1
1
27217
36.7
77
377
2652.5
153
256
3906.3
2
13607
73.5
78
374
2673.8
154
255
3921.6
3
11271
88.7
79
372
2688.2
155
254
3937.0
4
7970
125.5
80
369
2710.0
156
254
3937.0
5
5858
170.7
81
366
2732.2
157
253
3952.6
6
4564
219.1
82
364
2747.3
158
252
3968.3
7
3720
268.8
83
361
2770.1
159
251
3984.1
8
3132
319.3
84
358
2793.3
160
250
4000.0
9
2701
370.2
85
356
2809.0
161
249
4016.1
10
2373
421.4
86
354
2824.9
162
248
4032.3
11
2115
472.8
87
351
2849.0
163
248
4032.3
12
1908
524.1
88
349
2865.3
164
247
4048.6
13
1737
575.7
89
347
2881.8
165
246
4065.0
14
1594
627.4
90
344
2907.0
166
245
4081.6
15
1473
678.9
91
342
2924.0
167
244
4098.4
16
1369
730.5
92
340
2941.2
168
244
4098.4
17
1278
782.5
93
338
2958.6
169
243
4115.2
18
1199
834.0
94
336
2976.2
170
242
4132.2
19
1129
885.7
95
334
2994.0
171
241
4149.4
20
1066
938.1
96
332
3012.0
172
241
4149.4
21
1010
990.1
97
330
3030.3
173
240
4166.7
22
960
1041.7
98
328
3048.8
174
239
4184.1
23
916
1091.7
99
326
3067.5
175
238
4201.7
24
877
1140.3
100
324
3086.4
176
238
4201.7
25
842
1187.6
101
322
3105.6
177
237
4219.4
26
812
1231.5
102
321
3115.3
178
236
4237.3
27
784
1275.5
103
319
3134.8
179
235
4255.3
28
760
1315.8
104
317
3154.6
180
235
4255.3
29
737
1356.9
105
315
3174.6
181
234
4273.5
30
716
1396.6
106
314
3184.7
182
233
4291.8
31
697
1434.7
107
312
3205.1
183
233
4291.8
32
680
1470.6
108
310
3225.8
184
232
4310.3
33976
28
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
Table 30. Velocity Table (continued)
Velocity
Position
Time
Between
Steps (µs)
Velocity
(µSteps/s)
Velocity
Position
Time
Between
Steps (µs)
Velocity
(µSteps/s)
Velocity
Position
Time
Between
Steps (µs)
Velocity
(µSteps/s)
33
663
1508.3
109
309
3236.2
185
231
4329.0
34
648
1543.2
110
307
3257.3
186
231
4329.0
35
634
1577.3
111
306
3268.0
187
230
4347.8
36
621
1610.3
112
304
3289.5
188
229
4366.8
37
608
1644.7
113
303
3300.3
189
229
4366.8
38
596
1677.9
114
301
3322.3
190
228
4386.0
39
585
1709.4
115
300
3333.3
191
227
4405.3
40
575
1739.1
116
298
3355.7
192
227
4405.3
41
565
1769.9
117
297
3367.0
193
226
4424.8
42
555
1801.8
118
295
3389.8
194
226
4424.8
43
546
1831.5
119
294
3401.4
195
225
4444.4
44
538
1858.7
120
293
3413.0
196
224
4464.3
45
529
1890.4
121
291
3436.4
197
224
4464.3
46
521
1919.4
122
290
3448.3
198
223
4484.3
47
514
1945.5
123
289
3460.2
199
222
4504.5
48
507
1972.4
124
287
3484.3
200
222
4504.5
49
500
2000.0
125
286
3496.5
201
221
4524.9
50
493
2028.4
126
285
3508.8
202
221
4524.9
51
487
2053.4
127
284
3521.1
203
220
4545.5
52
481
2079.0
128
282
3546.1
204
220
4545.5
53
475
2105.3
129
281
3558.7
205
219
4566.2
54
469
2132.2
130
280
3571.4
206
218
4587.2
55
464
2155.2
131
279
3584.2
207
218
4587.2
56
458
2183.4
132
278
3597.1
208
217
4608.3
57
453
2207.5
133
277
3610.1
209
217
4608.3
58
448
2232.1
134
275
3636.4
210
216
4629.6
59
444
2252.3
135
274
3649.6
211
216
4629.6
60
439
2277.9
136
273
3663.0
212
215
4651.2
61
434
2304.1
137
272
3676.5
213
215
4651.2
62
430
2325.6
138
271
3690.0
214
214
4672.9
63
426
2347.4
139
270
3703.7
215
214
4672.9
64
422
2369.7
140
269
3717.5
216
213
4694.8
65
418
2392.3
141
268
3731.3
217
212
4717.0
33976
Analog Integrated Circuit Device Data
Freescale Semiconductor
29
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
Table 30. Velocity Table (continued)
Velocity
Position
Time
Between
Steps (µs)
Velocity
(µSteps/s)
Velocity
Position
Time
Between
Steps (µs)
Velocity
(µSteps/s)
Velocity
Position
Time
Between
Steps (µs)
Velocity
(µSteps/s)
66
414
2415.5
142
267
3745.3
218
212
4717.0
67
410
2439.0
143
266
3759.4
219
211
4739.3
68
406
2463.1
144
265
3773.6
220
211
4739.3
69
403
2481.4
145
264
3787.9
221
210
4761.9
70
399
2506.3
146
263
3802.3
222
210
4761.9
71
396
2525.3
147
262
3816.8
223
209
4784.7
72
393
2544.5
148
261
3831.4
224
209
4784.7
73
389
2570.7
149
260
3846.2
225
208
4807.7
74
386
2590.7
150
259
3861.0
75
383
2611.0
151
258
3876.0
Internal Clock Calibration
Timing-related functions on the 33976 (e.g., pointer
velocities, acceleration, and Return To Zero Pointer speeds)
depend upon a precise, consistent time reference to control
the pointer accurately and reliably. Generating accurate time
references on an integrated circuit can be accomplished. For
example trimming can be used however, it tends to be costly
due to the large amount of die area required for trim pads.
Another possibility is an externally generated clock signal;
however, this requires a dedicated pin on the device and
controller. An alternate approach would require the use of an
additional crystal or resonator, which is expensive.
The internal clock in the 33976 is temperature
independent and area efficient; however, it can vary by as
much as ±35 percent due to process variation. Using the
existing SPI inputs and the precision timing reference already
available to the microcontroller, the 33976 allows more
accurate clock calibration to within ±10 percent.
Calibrating the internal 1.0 MHz clock is initiated by writing
a logic [1] to PECCR bit PE3 (see Figure 10, page 30). The
8.0 µs calibration pulse is then provided by the controller to
ideally result in an internal 33976 clock speed of 1.0 MHz.
The pulse is sent on the CS pin immediately after the SPI
word is sent. During the calibration, no other SPI lines should
be toggled. At the moment the CS pin transitions from
logic [1] to logic [0], an internal 7-bit counter counts the
number of cycles of an internal, 8.0 MHz clock. The counter
stops when the CS pin transitions from logic [0] to logic [1].
The value in the counter represents the number of cycles of
the 8.0 MHz clock occurring in the 8.0 µs window; it should
range from 32 to 119. An offset is added to this number to
help center or skew the calibrated result to generate a
desired maximum or nominal frequency. The modified
counter value is truncated by 4 bits to generate the calibration
divisor, which should range from 4 to 15. The 8.0 MHz clock
is divided by the calibration divisor, resulting in a calibrated
1.0 MHz clock. If the calibration divisor lies outside the range
of 4 to 15, the 33976 flags the CAL bit in the device status
register, indicating the calibration procedure was not
successful. A clock calibration is allowed only if the gauges
are disabled or the pointers are not moving, as indicated by
status bits MOV1 and MOV0 (Table 20, page 21).
D0
D15
SI
SCLK
CS
PECCR Command
8.0 µs Calibration Pulse
Figure 10. Gauge Enable and Clock Calibration Example
33976
30
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
Some applications may require a guaranteed maximum
pointer velocity and acceleration. Guaranteeing these
maximums requires that the nominal internal clock frequency
falls below 1.0 MHz. The frequency range of the calibrated
clock will always be below 1.0 MHz if PECCR bit PE4 is
logic [0] prior to initiating a calibration command, followed by
an 8.0 µs reference pulse. The frequency will be centered at
1.0 MHz if bit D4 is logic [1].
The 33976 can be fooled into calibrating faster or slower
than the optimal frequency by sending a calibration pulse
longer or shorter than the intended 8.0 µs. As long as the
calibration divisor remains between 4 and 15 there will be no
clock calibration flag. For applications requiring a slower
calibrated clock — e.g., a motor designed with a gear ratio of
120:1 (8 microsteps/deg) — the user will have to provide a
longer calibration pulse. The device allows a SPI-selectable
slowing of the internal oscillator, using the PECCR command,
so that the calibration divisor safely falls within the 4-to-15
range when calibrating with a longer time reference. For
example, for the 120:1 motor, the pulse would be 12 µs
instead of 8.0 µs. The result of this slower calibration results
in the longer step times necessary to generate pointer
movements meeting acceleration and velocity requirements.
The resolution of the pointer positioning decreases from
0.083 deg/microstep (180:1) to 0.125 deg/microstep (120:1)
D
Ac
c
el
e
ra
t
e
VELOCITY
POSITION
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
ec
e
le
while the pointer sweep range increases from approximately
340 degrees to over 500 degrees.
Note Be aware that a fast calibration could result in
violations of the motor acceleration and velocity maximums,
resulting in missed steps.
Pointer Deceleration
Constant acceleration and deceleration of the pointer
produces relatively choppy movements when compared to
those of an air core gauge. Modifying the velocity position
ramp during deceleration can create the desired damped
movement. This modification is accomplished by adding
repetitive steps at several of the last velocity position step
values as the pointer decelerates. The 33976 allows the user
to tailor the response characteristics to the application with
three independent ramp characteristic variables. The RS,
HCP and HC variables can be used to change the slowest
velocity position steps, the number of Hold Counts, and the
number of ramp positions to which the Hold Counts apply.
More information is available in the RMPSEL description and
in the example shown in Figure 11. If the maximum
acceleration and deceleration of the pointer is desired, the
Hold Counts can be disabled dynamically by either writing a
logic [1] to the global Hold Count Disable bit, PECCR bit PE5,
or to the HE0 or HE1 bits of the POS0R or POS1R,
respectively.
First Velocity w/ Hold Counts = HCP × 8 + RS = 8 + 0 = 8
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
ra
te
Initial Velocity Position = RS + 1 = 0 + 1 = 1
Last Velocity w/ Hold Counts = RS + 2 = 0 + 2 = 2
Hold Counts per Step = HC = 3
For this example:
8
7
6
5
4
3
• RS = 0
• HC = 3
• HCP = 1
8
7
5
4
3
2
1
Position
6
= 0
2
1
0
MICROSTEPS
Figure 11. Deceleration Ramp
Return to Zero Calibration
Many step motor applications require that the IC detect
when the motor is stalled after commanded to return to the
zero position for calibration purposes. The stalling occurs
when the pointer hits the end stop on the gauge bezel, which
is usually at the zero position. It is important that when the
pointer reaches the end stop it immediately stops without
bouncing away.
The 33976 device provides the ability to automatically and
independently return each of the two pointers to the zero
position via the RTZR and RTZCR SPI commands. An
automatic RTZ is initiated using the RZ0, RZ1, and RZ2 bits
provided the RZ4 bit is a logic [0]. Unconditional RTZ
movement is initiated using the RZ0, RZ1, and RZ2 bits
provided the RZ4 bit is a logic [1]. During an RTZ event, all
commands related to the gauge being returned are ignored
until the pointer has successfully zeroed or the RTZR bit RZ1
is written to disable the event. Once an RTZ event is initiated,
the device reports back via the SO pin that an RTZ is
underway.
The RTZCR command is used to set the RTZ pointer
speed, choose an appropriate blanking time, and preload the
integration accumulator with an appropriate offset. On
reaching the end stop, the device reports back to the
33976
Analog Integrated Circuit Device Data
Freescale Semiconductor
31
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
microcontroller via the status message that the RTZ was
successful. The RTZ automatically disables, allowing other
commands to be valid. In the event the master determines an
RTZ sequence is not working properly (i.e., the RTZ taking
too long), it can disable the command via the RTZR bit RZ1.
RTZCR bits RC10:RC5 are written to preload the
accumulator with a predetermined value that will assure an
accurate pointer stall detection. This preloaded value is
determined during application development by disabling the
automatic shutdown feature of the device with the RTZR bit
RZ4. This operating mode allows the master to monitor the
RTZ event, using the accumulator information available via
the SO if the device is configured to provide the RTZ
Accumulator Status. The unconditional RTZ event can be
turned OFF using the RTZR bit RZ1.
If the Position 0 location bit is in the default logic [0] mode,
then during an RTZ event the pointer is returned counterclockwise (CCW) using full steps at a constant speed
determined by the RTZCR RC3:RC0 and RC12:RC11 bits
during RTZ configuration (see Figure 12). Full steps are used
during an RTZ so that only one coil of the motor is being
driven at any time. The coil not being driven is used to
determine if the pointer is moving. If the pointer is moving, the
EMF signal that is present in the non-driven coil is processed
by integrating the signal present on the opened pin of the coil
while essentially grounding the other end.
IMAX
ICOIL
0
SINE
IMAX
0
1
2
3
0
3
0
IMAX
COSINE
ICOIL
0
IMAX
0
1
2
Figure 12. Full Steps Counterclockwise
The IC automatically prepares the non-driven coil at each
step, waits for a predetermined blanking time, then
processes the signal for the duration of the full step. When
the pointer reaches the stop and no longer moves, the
dissipating flux is detected. The processed results are placed
in the RTZ accumulator, then compared to a decision
threshold. If the signal exceeds the decision threshold, the
pointer is assumed to be moving. If the threshold value is not
exceeded, the drive sequence is stopped if RTZR bit RZ4 is
logic [0]. If bit RZ4 is logic [1], the RTZ movement will
continue indefinitely until the RTZR bit RZ1 is used to stop the
RTZ event.
A pointer that is not on a full step location or that is in
magnetic alignment prior to the RTZ event may cause a false
RTZ detection. More specifically, an RTZ event beginning
from a non-full step position may result in an abbreviated
integration value potentially interpreted as a stalled pointer.
Advancing the pointer by at least 12 microsteps clockwise (if
PE7 = 0) to the nearest full step position (e.g., 0, 6, 12, 18,
24, etc.) prior to initiating an RTZ ensures the magnetic fields
line up and increases the chances of a successful pointer
stall detection. It is important that the pointer be in a static, or
commanded, position before starting the RTZ event.
Because the time duration and the number of steps the
pointer moves prior to reaching the commanded position can
vary depending upon its status at the time a position change
is communicated, the master should assure sufficient
elapsed time prior to starting an RTZ. If an RTZ is desired
after first enabling the outputs or after forcing a reset of the
device, the pointer should first be commanded to move
12 microsteps clockwise to the nearest full step location.
Because the pointer was in a static position at default, the
master could determine the number of microsteps the device
has taken by monitoring and counting the MOV0. MOV1
device status bit transitions to confirm the pointer is again in
a static position. Alternatively, the user could monitor the
device status bits CMD1 and CMD2.
33976
32
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
It should be pointed out that the flux value, for an ideal
motor with the coils perfectly aligned at 90°, will vary little
from full step to full step if all other variables (e.g.,
temperature) are held constant. The full steps are evenly
spaced which results in equidistant movement as the motor
is full stepped.
In comparison, motors that have coils aligned at a 60°
angle will result in two distinct flux values as the coils are
driven in the same full step fashion. This lack of symmetry in
the measured flux is due to the difference in the electrical
angles between full steps. In other words, the distance that
the rotor moves changes from full step to full step. This
difference can be observed in Figure 9 and Table 29. In
Figure 9, where PE6 = 0, the difference in microsteps
between alternating full steps (one coil at maximum current
while the other is at zero) is always six. In contrast, as seen
in Figure 9, where PE6 = 1, the difference in microsteps
between full steps of the 60° coils alternates between four
and eight. These expected differences need to be taken into
account when setting the RTZ threshold.
Only one gauge at a time can be returned to the zero
position. The gauge not returning to zero can continue to be
controlled. An RTZ should not begin until the gauge to be
calibrated is at a static position and its pointer is at a full step
position. An attempt to calibrate a gauge while the other is in
the process of an RTZ event is ignored by the device. In most
applications of the RTZR command, it is possible to avoid a
visually obvious sequential calibration by first bringing the
pointers back close to their previous zero positions, then recalibrating them sequentially.
After completion of an RTZ, the 33976 automatically
assigns the zero-step position to the full step position at the
end-stop location. Because the actual zero position could lie
anywhere within the full step where the zero was detected,
the assigned zero position could be within a window of ±0.5
degree. An RTZ can be used to detect stall, even if the
pointer already rests on the end stop when an RTZ sequence
is initiated. However, it is recommended the pointer be
advanced by at least 12 microsteps to the nearest full step
prior to initiating the RTZ.
RTZ OUTPUT
During an RTZ event the non-driven coil is analyzed to
determine the state of the motor. The 33976 multiplexes the
coil voltages and provides the signal from the non-driven coil
to the RTZ pin.
disabled after a power-up or external reset, and SO flag OD6
and OD8 are set, indicating an undervoltage event. Anytime
an external reset is exerted and the default is restored, all
configuration parameters (e.g., clock calibration, maximum
speed, RTZ parameters, etc.) are lost and must be reloaded.
FAULT LOGIC REQUIREMENTS
The 33976 device indicates each of the following faults as
they occur:
•Overtemperature fault
•Undervoltage VPWR
•Overvoltage VPWR
•Clock out of spec
These fault bits remain enabled until they are clocked out
of the SO pin with a valid SPI message.
Overcurrent faults are not reported directly; however, it is
likely an overcurrent condition will become a thermal issue
and be reported.
Overtemperature Fault Requirements
The 33976 incorporates overtemperature protection
circuitry, which shuts off the affected gauge driver when
excessive temperatures are detected. In the event of a
thermal overload, the affected gauge driver is automatically
disabled. The overtemperature fault is flagged via the OT0
and/or OT1 device status bits. The indicating flag continues
to be set until the affected gauge is successfully re-enabled,
provided the junction temperature has fallen to a temperature
below the hysteresis level.
OVERVOLTAGE FAULT REQUIREMENTS
The device is capable of surviving VPWR voltages within
the maximum specified in Maximum Ratings table, page 4.
VPWR levels resulting in an Overvoltage Shutdown condition
can result in uncertain pointer positions. Therefore, the
pointer position should be re-calibrated. The master will be
notified of an overvoltage event via the SO pin if the device
status is selected. Overvoltage detection and notification
occurs regardless of whether the gauge(s) are enabled or
disabled.
Overcurrent Fault Requirements
Output currents are limited to safe levels allowing the
device to rely on thermal shutdown to protect itself.
Undervoltage Fault Requirements
DEFAULT MODE
Default mode refers to the state of the 33976 after an
internal or external reset prior to SPI communication. An
internal reset occurs during VDD power-up or if VPWR falls
below 4.0 V. An external reset is initiated by the RST pin
driven to a logic [0]. With the exception of the RTZCR full step
time and the RMPSEL Register values, all of the specific pin
functions and internal registers will operate as though all of
the addressable configuration register bits were set to
logic [0]. This means, for example, all of the outputs will be
Undervoltage VPWR conditions may result in uncertain
pointer positions. Therefore, the internal clock and the pointer
position may require re-calibration. The state machine
continues with VPWR voltage levels as low as 4.0 V; however,
the coil voltages may be clipped. The master can be notified
of an undervoltage event via the SO pin.
RESET (SLEEP MODE)
The device can reset internally or externally. If the VDD
level falls below the VDDUV level (refer to the Static Electrical
33976
Analog Integrated Circuit Device Data
Freescale Semiconductor
33
FUNCTIONAL DEVICE OPERATION
LOGIC COMMANDS AND REGISTERS
Characteristics table under POWER INPUT, page 5), the
device resets and powers up in the Default mode. Similarly,
If the RST pin is driven to a logic [0], the device resets to its
default state. The device consumes the least amount of
current (IDD and IPWR) when the RST pin is logic [0]. This is
also referred to as the Sleep mode.
33976
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Freescale Semiconductor
TYPICAL APPLICATIONS
TYPICAL APPLICATIONS
The 33976 is an extremely versatile device that can be
used in a variety of applications. The flexibility has been
significantly improved, over that of the older MC33991 and
MC33970 devices, with the addition of the Velocity Ramp
configuration features that are available in the RMPSEL
register (see Table 31). Some applications (e.g., high
performance tachometers) require responsive pointers that
change directions quickly. Figure 10 shows some
characteristics of the ramp modifications that are possible
with the RMPSELR RS bit.
6000.0
13ms
5000.0
33991
63ms
33991
Speed (usteps / s)
4000.0
Ideal Acceleration
(4500 deg/s^2)
33976 (RS = 4)
3000.0
33970
or
33976
Default
2000.0
GDIC MC33991
GDIC MC33970 or MC33976 default
1000.0
Ideal Acceleration (4500 deg/s^2)
GDIC MC33976 ramp w/first step = 5
0.0
0
20000
40000
60000
80000
100000
120000
140000
160000
180000
Time(µs)
(us)
Time
Figure 13. Start / Stop Response Characteristics
Other applications (e.g., speedometers and fuel
page 36, gives several examples of different damping
characteristics that are possible with the device. Once
indicators) require smooth, low speed movement. For these
configured, the damping can be dynamically enabled and
applications, the damping of the pointer can be optimized
disabled using the HE bits of the Position registers.
with the HC and HCP bits of the RMPSELR. Figure 14,
33976
Analog Integrated Circuit Device Data
Freescale Semiconductor
35
TYPICAL APPLICATIONS
1250
1200
33970
33976
1100
1050
33976 Default
(16, 5 ≡ HCP×8, HC)
1000
950
Position (usteps)
Position (microsteps)
1150
900
850
800
0
0.1
0.2
0.3
0.4
Tim e (s)
GDIC1.5
33970
NO HOLDS
0.5
0.6
64,4
64, 4
0.7
0.8
32-44
32,
0.9
16-5
16, 5
1
8-44
8,
Figure 14. 33976 Damping Response Examples
device could be used. Further, it is intended to familiarize
users with some of its capabilities.
Table 31 provides a step-by-step example of configuring
and using many of the features designed into the IC. This
example is intended to give a generic overview how the
Table 31. 33976 Setup, Configuration, and Usage Example
Step
Command
1
PECCR
Description
Enable Gauges
Bit PE0: Gauge 0
Bit PE1: Gauge 1
Reference Table
and/or Figure
Table 7 (page 14),
Figure 10
(page 30)
Clock Calibration
Bit PE3: Enables Calibration Procedure
Bit PE4: Set clock f = 1.0 MHz maximum or nominal
Send 8.0 µs pulse on CS to calibrate 1.0 MHz clock
2
RTZCR
Set RTZ Full Step Time
Bits RC3:RC0
Table 12
(page 18),
Table 13 (page 18)
Set RTZ Blanking Time
Bit RC4
Preload RTZ Accumulator
Table 14 (page 19)
Bits RC12:RC11 and RC10:RC5
Check SO for an Out-of-Range Clock Calibration
Is bit CAL logic [1]? If so, then repeat Steps 1 and 2
Table 7 (page 14),
Table 20 (page 21)
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Analog Integrated Circuit Device Data
Freescale Semiconductor
TYPICAL APPLICATIONS
Table 31. 33976 Setup, Configuration, and Usage Example (continued)
Description
Reference Table
and/or Figure
Step
Command
3
POS0R
Move pointer to position 12 prior to RTZ
Table 9 (page 16)
4
POS1R
Move pointer to position 12 prior to RTZ
Table 10 (page 16)
Check SO to see if Gauge 0 has moved
Table 7 (page 14),
Table 20 (page 21)
Is bit MOV0 (OD4) logic [1]? If so, then the Gauge 0 has moved to the first microstep
5
PECCR
Send null command to see if gauges have moved
Table 7 (page 14)
Bit PE12
Check SO to see if Gauge 0 (Gauge 1) has moved
Is bit MOV0 (OD4) (MOV1 (OD5)) logic [1]? If so, then Gauge 0 (Gauge 1) moved another
microstep. Keep track of movement and if 12 steps are finished and both gauges are at
a static position, then RTZ. Otherwise, repeat steps (a) and (b)
Table 7 (page 14),
Table 20 (page 21)
Bit CMD0 (OD10) (CMD1 (OD11)) could also be monitored to determine that the pointer
is static
6
RTZ
Return one gauge at a time to the zero stop using RTZ command
Table 11 (page 17)
Bit RZ0 selects the gauge
Bit RZ1 is used to enable or disable an RTZ
Bits RZ2 is used to select the direction (along with PE7)
7
PECCR
Select the RTZ accumulator bits to clock out on the SO bits using bits PE11:PE10. These
will be used if characterizing the RTZ.
Table 7 (page 14),
Table 22 (page 23)
Check the Status of the RTZ by sending the null command to monitor SO bit RTZ0, RTZ1 of
Device Status SO
Table 7 (page 14),
Table 20 (page 21)
Bit PE12 is the null command
Is RTZ0 (OD2) logic [0]? If not, Gauge 0 still returning and null command should be resent
8
RTZ
Return the other gauge to the zero stop. If the second gauge is driving a different pointer than
the first, a new RTZCR command may be required to change the Full Step time
Table 11 (page 17)
9
PECCR
Check the Status of the RTZ by sending the null command to monitor SO, bit RTZ1 (OD3)
Table 7 (page 14),
Table 20 (page 21)
Bit PE12 is the null command
Is RTZ1 (OD3) logic [0]? If not, Gauge 1 still returning and null command should be resent
10
VELR
Change the maximum velocity of the gauge
Bits V8:V9 determine which gauge(s) will change the maximum velocity
Table 7 (page 15),
Table 30 (page 28)
Bits V7:V0 determine the maximum velocity position from Table 30, Velocity Table
11
POS0R
Position Gauge 0 pointer
Bits P011:P00: Desired Pointer Position
Table 9 (page 16),
Table 30 (page 28)
Check SO for Out-of-Range VPWR
Bit OVUV (OD6) logic [1]? If so, use UV (OD8) and OV (OD9) to decide whether to RTZ
after valid VPWR
Check SO for overtemperature
Bit OT0 logic [1]? If so, enable driver again. If OT0 continues to indicate overtemperature,
shut down Gauge 0
If RTZ0 returns to normal, re-establish the zero reference by RTZ command
33976
Analog Integrated Circuit Device Data
Freescale Semiconductor
37
TYPICAL APPLICATIONS
Table 31. 33976 Setup, Configuration, and Usage Example (continued)
Step
Command
12
POS1R
Reference Table
and/or Figure
Description
Position Gauge 1 pointer
Table 10 (page 16),
Table 30 (page 28)
Bits P1 11:P1 0: Desired Pointer Position
Check SO for Out-of-Range VPWR
Bit OVUV logic [1]? If so, use UV (OD8) and OV (OD9) to decided whether to RTZ after
valid VPWR
Check SO for overtemperature
Bit OT1 logic [1]? If so, enable driver again. If OT1 continues to indicate overtemperature,
shut down Gauge 1.
If OT1 returns to normal, re-establish the zero reference by RTZ command
13
POS0R
Return the pointers close to zero position using POS0R
Table 9 (page 16)
Move pointer position at least 12 microsteps CW to the nearest full step prior to RTZ
14
POS1R
Return the pointers close to zero position using POS1R
Table 10 (page 16)
Move pointer position at least 12 microsteps CW to the nearest full step position prior to RTZ
Check SO to see if Gauge 0 has moved
Table 10 (page 16),
Table 20 (page 21)
Bit MOV0 logic [1]? If so, Gauge 0 moved to the first microstep
15
PECCR
Send null command to see if gauges have moved
Table 7 (page 14),
Table 20 (page 21)
Bits PE12
Check SO to see if Gauge 0 (Gauge 1) moved
Bit MOV0 (MOV1) logic [1]? If so, Gauge 0 (Gauge 1) moved another microstep. Keep
track of movement. If 12 steps are finished, and both gauges are at a static position, then
RTZ. Otherwise repeat steps (a) and (b)
Bit CMD0 (OD10) (CMD1 (OD1)) could also be monitored to determine that the pointer is
static
16
RTZ
Return one gauge at a time to the zero stop using RTZ command
Table 7 (page 14),
Table 11 (page 17),
Table 22 (page 23)
Bit RZ0 selects the gauge
Bit RZ1 is used to enable or disable an RTZ
Bit RZ2 is used to select the direction (along with PE7)
Select the RTZ accumulator bits clocking out on the SO bits using bits PE11:PE10. These
will be used if characterizing the RTZ
17
PECCR
Check the status of the RTZ by sending the null command to monitor SO bit RTZ0
Bit PE12 is the null command
Table 7 (page 14),
Table 20 (page 21)
Is RTZ0 logic [0]? If not, Gauge 0 still returning and null command should be resent
18
RTZ
19
PECCR
Return the other gauge to the zero stop. If the second gauge is driving a different pointer than
the first, a new RTZCR command may be required to change the Full Step time
Table 11 (page 17),
Table 14 (page 19)
Check the status of the RTZ by sending the null command to monitor SO bit RTZ1
Table 7 (page 14),
Table 20 (page 21)
Bit PE12 is the null command
20
PECCR
Is RTZ1 logic [0]? If not, Gauge 1 still returning and null command should be resent
Table 11 (page 17)
Disable both gauges and go to standby
Table 7 (page 14)
Bit PE0:PE1 are used to disable the gauges
Put the device to sleep
RST pin is pulled to logic [0]
33976
38
Analog Integrated Circuit Device Data
Freescale Semiconductor
PACKAGING
PACKAGE DIMENSIONS
PACKAGING
PACKAGE DIMENSIONS
For the most current package revision, visit www.freescale.com and perform a keyword search using the “98A” listed below.
DW SUFFIX
EG SUFFIX (PB-FREE)
24-LEAD SOICW
PLASTIC PACKAGE
98ASB42344B
ISSUE F
33976
Analog Integrated Circuit Device Data
Freescale Semiconductor
39
REVISION HISTORY
REVISION HISTORY
REVISION
3.0
4.0
DATE
8/2006
1/2007
DESCRIPTION OF CHANGES
•
•
•
•
•
•
•
•
•
•
•
•
•
•
Implemented Revision History page
Converted to Freescale format
Updated package drawing
Corrected symbol labels on Microstep Output (Measured Across Coil Outputs) and
Output Flyback Clamp (11)
Added maximum pointer calculation on page 16
Corrected detect threshold upper range from 4081 to 1009
Changed internal clock variation from 35% to 70%
Changed EMF to flux on page 31
Added MCZ33976EG/R2 to the Ordering Information block.
Revised Internal Block Diagram to enhance readability
Added parameter Peak Package Reflow Temperature During Reflow (4), (5) on page 4
and notes (4) and (5)
Added ADC Gain (10), (14) to Static Electrical Characteristics table
Made wording additions to Address 101 — Gauge Return to Zero Configuration Register
on page 17 and RC12:RC11 = M; default value = 00 on page 18
Added RTZ Accumulator (Typical) on page 23 and accompanying text
33976
40
Analog Integrated Circuit Device Data
Freescale Semiconductor
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MC33976
Rev 4.0
1/2007
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