参数资料
| 型号: | MC33970DWR2 |
| 厂商: | Freescale Semiconductor |
| 文件页数: | 14/36页 |
| 文件大小: | 0K |
| 描述: | IC GAUGE DRIVER SPI 24-SOIC |
| 标准包装: | 1 |
| 应用: | 步进电机驱动器,2 相 |
| 输出数: | 2 |
| 电流 - 输出: | 100mA |
| 电压 - 负载: | 6.5 V ~ 26 V |
| 电源电压: | 4.5 V ~ 5.5 V |
| 工作温度: | -40°C ~ 125°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 24-SOIC(0.295",7.50mm 宽) |
| 供应商设备封装: | 24-SOIC W |
| 包装: | 带卷 (TR) |
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�
�FUNCTIONAL� DEVICE� OPERATION�
�LOGIC� COMMANDS� AND� REGISTERS�
�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� 33970� 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� μ� s�
�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�
��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� μ� s�
�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� μ� s.� Unless� the� internal� oscillator� is� slowed� by�
�writing� PE2� to� logic� [1],� a� 12� μ� s� 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.�
�This� feature� is� enabled� with� the� device� that� is� in� the� default�
�mode.� Writing� logic� [1]� to� bit� PE5� will� disable� the� air� core�
�emulation� and� provide� a� constant� acceleration� and�
�deceleration� at� the� maximum� rate.�
�Bit� D6� is� logic� [0]� during� a� PECCR� commands.�
�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� 21� ,� page� 24� (PE10,� PE9,� and� PE8�
�logic� [1]).�
�Additional� details� are� provided� in� the� SO Communication�
��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�
�Read�
�Write�
�D12�
�–�
�PE12�
�D11�
�–�
�PE11�
�D10�
�–�
�PE10�
�D9�
�–�
�PE9�
�D8�
�–�
�PE8�
�D7�
�–�
�PE7�
�D6�
�–�
�0�
�D5�
�–�
�PE5�
�D4�
�–�
�PE4�
�D3�
�–�
�PE3�
�D2�
�–�
�PE2�
�D1�
�–�
�PE1�
�D0�
�–�
�PE0�
�The� bits� in� Table� 7� are� write-only� .�
�PE12� (D12)� —� Null� Command� for� Status� Read�
�?� 0� =� Disable�
�?� 1� =� Enable�
�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�
�33970�
�Analog� Integrated� Circuit� Device� Data�
�14�
�Freescale� Semiconductor�
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