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Holtek MCU HT32F65532G

HT32F65532G device is a high performance, low power consumption 32-bit microcontroller based around an Arm® Cortex®-M0+ processor core.

General Description

The Holtek HT32F65532G device is a high performance, low power consumption 32-bit  microcontroller based around an Arm® Cortex®-M0+ processor core. The Cortex®-M0+ is a nextgeneration processor core which is tightly coupled with Nested Vectored Interrupt Controller  (NVIC), SysTick timer and advanced debug support.

The device operates at a frequency of up to 60 MHz with a Flash accelerator to obtain maximum  efficiency. It provides 32 KB of embedded Flash memory for code/data storage and 4 KB of  embedded SRAM memory for system operation and application program usage. A variety of  peripherals, such as Hardware Divider DIV, ADC, OPA, CMP, I2 C, USART, UART, SPI, MCTM,  GPTM, SCTM, BFTM, CRC-16/32, LSTM, WDT, PDMA, SW-DP (Serial Wire Debug Port),  etc., are also implemented in the device. Several power saving modes provide the flexibility for  maximum optimization between wakeup latency and power consumption, an especially important  consideration in low power applications.

The device also includes a gate-driver for 3-phase motor driving applications. The gate-driver has  several internal protection functions and provides an integrated 5V low quiescent current LDO  which can provide power supply for external circuits.

The above features ensure that the device is suitable for use in a wide range of applications,  especially in areas such as electric scooters, kitchen ventilators, vacuum cleaners, pumps, funs and  so on.

Product Features

  • Core

    ▆ 32-bit Arm® Cortex®-M0+ processor core

    ▆ Up to 60 MHz operating frequency

    ▆ Single-cycle multiplication

    ▆ Integrated Nested Vectored Interrupt Controller (NVIC)

    ▆ 24-bit SysTick timer

    The Cortex®-M0+ processor is a very low gate count, highly energy efficient processor that is  intended for microcontroller and deeply embedded applications that require an area optimized,  low-power processor. The processor is based on the ARMv6-M architecture and supports Thumb® instruction sets, single-cycle I/O ports, hardware multiplier and low latency interrupt respond time.

  • On-chip Memory

    ▆ 32 KB on-chip Flash memory for instruction/data and options storage

    ▆ 4 KB on-chip SRAM

    ▆ Supports multiple booting modes

    The Arm® Cortex®-M0+ processor access and debug access share the single external interface to  external AHB peripherals. The processor access takes priority over debug access. The maximum  address range of the Cortex®-M0+ is 4 GB since it has a 32-bit bus address width. Additionally,  a pre-defined memory map is provided by the Cortex®-M0+ processor to reduce the software  complexity of repeated implementation by different device vendors. However, some regions are  used by the Arm® Cortex®-M0+ system peripherals. Refer to the Arm® Cortex®-M0+ Technical  Reference Manual for more information. Figure 2 in the Overview chapter shows the memory map  of the HT32F65532G device, including code, SRAM, peripheral and other pre-defined regions.

  • Flash Memory Controller – FMC

    ▆ Flash accelerator to obtain maximum efficiency

    ▆ 32-bit word programming with In System Programming Interface (ISP) and In Application  Programming (IAP)

    ▆ Flash protection capability to prevent illegal access

    The Flash Memory Controller, FMC, provides all the necessary functions and pre-fetch buffer for  the embedded on-chip Flash Memory. Since the access speed of the Flash Memory is slower than  the CPU, a wide access interface with a pre-fetch buffer is provided for the Flash Memory in order  to reduce the CPU waiting time which will cause CPU instruction execution delays. Flash Memory  word programming/page erase functions are also provided.

  • Reset Control Unit – RSTCU

    ▆ Supply supervisor

    ● Power On Reset / Power Down Reset – POR / PDR

    ● Brown-Out Detector – BOD

    ● Programmable Low Voltage Detector – LVD

    The Reset Control Unit, RSTCU, has three kinds of reset, a power on reset, a system reset and an  APB unit reset. The power on reset, known as a cold reset, resets the full system during power up.  A system reset resets the processor core and peripheral IP components with the exception of the  SW-DP controller. The resets can be triggered by external signals, internal events and the reset  generators.

  • Clock Control Unit – CKCU

    ▆ External 4 to 16 MHz crystal oscillator

    ▆ Internal 8 MHz RC oscillator trimmed to ± 2 % accuracy at 3.3 V operating voltage and 25 °C  operating temperature

    ▆ Internal 32 kHz RC oscillator

    ▆ Integrated system clock PLL

    ▆ Independent clock divider and gating bits for peripheral clock sources

    The Clock Control Unit, CKCU, provides a range of oscillator and clock functions. These include  High Speed Internal RC oscillator (HSI), High Speed External crystal oscillator (HSE), Low Speed  Internal RC oscillator (LSI), Phase Lock Loop (PLL), HSE clock monitor, clock prescaler, clock  multiplexer, APB clock divider and gating circuitry. The clocks of AHB, APB and Cortex®-M0+  are derived from system clock (CK_SYS) which can come from HSI, HSE, LSI or system PLL.  Watchdog Timer (WDT) and Low Speed Timer (LSTM) use the LSI as their clock source.

  • Power Management Control Unit – PWRCU

    ▆ VDD power supply: 2.5 V to 5.5 V

    ▆ Integrated 1.5 V LDO regulator for MCU core, peripherals and memories power supply

    ▆ VDD and VCORE power domains

    ▆ Two power saving modes: Sleep and Deep-Sleep modes

    Power consumption can be regarded as one of the most important issues for many embedded  system applications. Accordingly the Power Control Unit, PWRCU, in the device provides two  types of power saving modes which are the Sleep and Deep-Sleep modes. These operating modes  reduce the power consumption and allow the application to achieve the best trade-off between the  conflicting demands of CPU operating time, speed and power consumption.

  • Gate-Driver

    ▆ Wide power supply range: VCC = 6 V ~ 40 V

    ▆ Maximum motor sustainable voltage up to 48 V

    ▆ 3-channel half-bridge driver: Drives 3 high-side and 3 low-side N-type MOSFETs

    ▆ Integrated 5 V LDO regulator (VREG) with 50mA output drive current

    ▆ Integrated gate-driver power supplies:

    ● High-side bootstrap driving: supports up to 50 kHz PWM operation

    ● Low-side driving: 12 V linear regulator (V12P)

    ▆ Integrated 120ns fixed dead time control

    ▆ High-side and low-side gate-driver control

    ● High-side: High active (INHx)

    ● Low-side: Low active (INLx)

    ▆ Protection features

    ● VCC Under Voltage Lock-Out (VCC_UVLO)

    ● VBSTx Under Voltage Lock-Out (VBST_UVLO)

    ● V12P Under Voltage Lock-Out (V12P_UVLO)

    ● VREG Under Voltage Lock-Out (VREG_UVLO)

    ● Over Temperature Protection (OTP)

  • External Interrupt/Event Controller – EXTI

    ▆ Up to 16 EXTI lines with configurable trigger source and type

    ▆ All GPIO pins can be selected as EXTI trigger source

    ▆ Source trigger type includes high level, low level, negative edge, positive edge or both edges

    ▆ Individual interrupt enable, wakeup enable and status bits for each EXTI line

    ▆ Software interrupt trigger mode for each EXTI line

    ▆ Integrated deglitch filter for short pulse blocking

    The External Interrupt/Event Controller, EXTI, comprises 16 edge detectors which can generate  wake-up events or interrupt requests independently. Each EXTI line can also be masked  independently.

  • Analog to Digital Converter – ADC

    ▆ 12-bit SAR ADC engine

    ▆ Up to 2 Msps conversion rate

    ▆ Up to 12 external analog input channels

    A 12-bit multi-channel Analog to Digital Converter is integrated in the device. There are  multiplexed channels, which include 12 external channels on which the external analog signal can  be supplied and 3 internal channels. If the input voltage is required to remain within a specific  threshold window, the ADC analog watchdog function will monitor and detect the signal. An  interrupt will then be generated to inform the device that the input voltage is higher or lower than  the set thresholds. There are three conversion modes to convert an analog signal to digital data. The  A/D conversion can be operated in one shot, continuous and discontinuous conversion modes

  • Operational Amplifier – OPA

    ▆ Fixed dedicated I/O pins

    ▆ Internal output paths to the A/D converter or comparator

    ▆ Input offset calibration

    ▆ 10-bit DAC offset voltage

  • Comparator – CMP

    ▆ Two rail-to-rail comparators

    ▆ Each comparator has configurable inverting or non-inverting inputs used for flexible voltage  selection

    ● Dedicated I/O pins

    ● Internal voltage reference provided by 8-bit scaler – CMP0 only

    ● Internal operational amplifier output

    ▆ Programmable hysteresis

    ▆ Programming response speed and power consumption

    ▆ Comparator output can be routed to I/O pin or to multiple timers or ADC trigger input

    ▆ 8-bit scaler can be configured to dedicated I/O for voltage reference

    ▆ Configurable inverting input from CMP0N, CMP1N or CVREF

    ▆ Interrupt generation capability with wakeup from Sleep or Deep Sleep mode through the EXTI  controller

    Two general purpose comparators are implemented within the device. They can be configured  either as standalone comparators or combined with different kinds of peripheral IP. Each  comparator is capable of asserting interrupts to the NVIC or waking up the MCU from the Sleep or  Deep Sleep mode through the EXTI wakeup event management unit.

  • I/O Ports – GPIO

    ▆ Up to 28 GPIOs

    ▆ Port A, B, C are mapped as 16 external interrupts – EXTI

    ▆ Almost all I/O pins have configurable output driving current

    There are up to 28 General Purpose I/O pins, GPIO, for the implementation of logic input / output  functions. Each of the GPIO ports has a series of related control and configuration registers to  maximize flexibility and to meet the requirements of a wide range of applications.

    The GPIO ports are pin-shared with other alternative functions (AFs) to obtain maximum  functional flexibility on the package pins. The GPIO pins can be used as alternative functional  pins by configuring the corresponding registers regardless of the input or output pins. The external  interrupts on the GPIO pins of the device have related control and configuration registers in the  External Interrupt Control Unit, EXTI.

  • Motor Control Timer – MCTM

    ▆ 16-bit up / down auto-reload counter

    ▆ 16-bit programmable prescaler that allows division of the prescaler clock source by any factor  between 1 and 65536 to generate the counter clock frequency

    ▆ Input Capture function

    ▆ Compare Match Output

    ▆ PWM waveform generation with edge-aligned and center-aligned counting modes

    ▆ Single Pulse Mode Output

    ▆ Complementary outputs with programmable dead-time insertion

    ▆ Break input signals to assert the timer output signals in reset state or in a known fixed state

    The Motor Control Timer, MCTM, consists of one 16-bit up / down-counter, four 16-bit Capture /  Compare Registers (CCRs), one 16-bit Counter Reload Register (CRR), one 8-bit repetition counter  and several control / status registers. It can be used for a variety of purposes which include input  signal pulse width measurement, output waveform generation for signals such as compare match  outputs, PWM outputs or complementary PWM outputs with dead-time insertion. The MCTM  is capable of offering full functional support for motor control, hall sensor interfacing and break  input.

  • General-Purpose Timer – GPTM

    ▆ 16-bit up / down auto-reload counter

    ▆ Up to 4 independent channels for each timer

    ▆ 16-bit programmable prescaler that allows division of the prescaler clock source by any factor  between 1 and 65536 to generate the counter clock frequency

    ▆ Input Capture function

    ▆ Compare Match Output

    ▆ PWM waveform generation with edge-aligned and center-aligned counting modes

    ▆ Single Pulse Mode Output

    ▆ Encoder interface controller with two inputs using quadrature decoder and Pulse/Direction Mode

    ▆ Master/Slave mode controller

    The General-Purpose Timer, GPTM, consists of one 16-bit up / down-counter, four 16-bit Capture  / Compare Registers (CCRs), one 16-bit Counter Reload Register (CRR) and several control / status  registers. It can be used for a variety of purposes including general timer, input signal pulse width  measurement, output waveform generation such as single pulse generation or PWM outputs. The  GPTM also supports an encoder interface using a quadrature decoder with two inputs.

  • Single Channel Timer – SCTM

    ▆ 16-bit auto-reload up-counter

    ▆ One channel for each timer

    ▆ 16-bit programmable prescaler that allows division of the prescaler clock source by any factor  between 1 and 65536 to generate the counter clock frequency

    ▆ Input Capture function

    ▆ Compare Match Output

    ▆ PWM waveform generation with edge-aligned counting mode

    The Single Channel Timer, SCTM, consists of one 16-bit up-counter, one 16-bit Capture / Compare  Register (CCR), one 16-bit Counter-Reload Register (CRR) and several control / status registers. It  can be used for a variety of purposes including general timer, input signal pulse width measurement  or output waveform generation such as PWM outputs.

  • Basic Function Timer – BFTM

    ▆ 32-bit compare match up-counter – no I/O control features

    ▆ One shot mode – stops counting when compare match occurs

    ▆ Repetitive mode – restarts counter when compare match occurs

    The Basic Function Timer, BFTM, is a simple 32-bit up-counting counter designed to measure time  intervals, generate one shot pulses or generate repetitive interrupts. The BFTM can operate in two  modes which are repetitive and one shot modes. In the repetitive mode, the counter is restarted at  each compare match event. The BFTM also supports a one shot mode which will force the counter  to stop counting when a compare match event occurs.

  • Watchdog Timer – WDT

    ▆ 12-bit down-counter with 3-bit prescaler

    ▆ Provides reset to the system

    ▆ Programmable watchdog timer window function

    ▆ Register write protection function

    The Watchdog Timer is a hardware timing circuitry that can be used to detect a system lock-up  due to software trapped in a deadlock. It includes a 12-bit count-down counter, a prescaler, a WDT  delta value register, WDT operation control circuitry and a WDT protection mechanism. If the  software does not reload the counter value before a Watchdog Timer underflow occurs, a reset will  be generated when the counter underflows. In addition, a reset is also generated if the software  reloads the counter before it reaches a delta value. It means that the counter reload must occur  when the Watchdog timer value has a value within a limited window using a specific method. The  Watchdog Timer counter can be stopped when the processor is in the debug mode. The register  write protection function can be enabled to prevent an unexpected change in the Watchdog timer  configuration.

  • Low Speed Timer – LSTM

    ▆ 24-bit up-counter with a programmable prescaler

    ▆ Alarm function

    ▆ Interrupt and wake-up control

    The Low Speed Timer, LSTM, circuitry includes the APB interface, a 24-bit count-up counter, a  control register, a prescaler, a compare register and a status register. The LSTM circuits are located  in the VCORE power domain. When the device enters the power-saving mode, the LSTM counter is  used as a wakeup timer to let the system resume from the power saving mode.

  • Inter-Integrated Circuit – I2 C

    ▆ Supports both master and slave modes with a frequency of up to 1 MHz

    ▆ Provides an arbitration function and clock synchronization

    ▆ Supports 7-bit and 10-bit addressing modes and general call addressing

    ▆ Supports slave multi-addressing mode using address mask function

    The I2 C module is an internal circuit allowing communication with an external I2 C interface which  is an industry standard two-wire serial interface used for connection to external hardware. These  two serial lines are known as a serial data line SDA, and a serial clock line SCL. The I2 C module  provides three data transfer rates: 100 kHz in the Standard mode; 400 kHz in the Fast mode; 1  MHz in the Fast plus mode. The SCL period generation registers are used to set different kinds of  duty cycle implementation for the SCL pulse.

    The SDA line which is connected directly to the I2 C bus is a bidirectional data line between the  master and slave devices and is used for data transmission and reception. The I2 C module also has  an arbitration detection and clock synchronization function to prevent situations where more than  one master attempts to transmit data to the I2 C bus at the same time.

  • Serial Peripheral Interface– SPI

    ▆ Supports both master and slave modes

    ▆ Frequency of up to (fPCLK/2) MHz for the master mode and (fPCLK/3) MHz for the slave mode

    ▆ FIFO Depth: 8 levels

    ▆ Multi-master and multi-slave operation

    The Serial Peripheral Interface, SPI, provides an SPI protocol data transmit and receive function in  both master and slave modes. The SPI interface uses 4 pins, among which are serial data input and  output lines MISO and MOSI, the clock line SCK, and the slave select line SEL. One SPI device  acts as a master who controls the data flow using the SEL and SCK signals to indicate the start of  the data communication and the data sampling rate. To receive the data bits, the streamlined data  bits are latched on a specific clock edge and stored in the data register or in the RX FIFO. Data  transmission is carried out in a similar way but with the reverse sequence. The mode fault detection  provides a capability for multi-master applications.

  • Universal Asynchronous Receiver Transmitter – UART

    ▆ Asynchronous serial communication operating baud-rate clock frequency up to (fPCLK/16) MHz

    ▆ Full duplex communication

    ▆ Fully programmable serial communication characteristics including:

    ● Word length: 7, 8 or 9-bit character

    ● Parity: Even, odd or no-parity bit generation and detection

    ● Stop bit: 1 or 2 stop bits generation

    ● Bit order: LSB-first or MSB-first transfer

    ▆ Error detection: Parity, overrun and frame error

    The Universal Asynchronous Receiver Transceiver, UART, provides a flexible full duplex data  exchange using asynchronous transfer. The UART is used to translate data between parallel and  serial interfaces, and is commonly used for RS232 standard communication. The UART peripheral  function supports Line Status Interrupt. The software can detect a UART error status by reading  the UART Status & Interrupt Flag Register, URSIFR. The status includes the type and the  condition of transfer operations as well as several error conditions resulting from Parity, Overrun,  Framing and Break events.

  • Universal Synchronous Asynchronous Receiver Transmitter – USART

    ▆ Supports both asynchronous and clocked synchronous serial communication modes

    ▆ Programmable baud rate clock frequency up to (fPCLK/16) MHz for asynchronous mode and  (fPCLK/8) MHz for synchronous mode

    ▆ Full duplex communication

    ▆ Fully programmable serial communication characteristics including:

    ● Word length: 7, 8 or 9-bit character

    ● Parity: Even, odd or no-parity bit generation and detection

    ● Stop bit: 1 or 2 stop bits generation

    ● Bit order: LSB-first or MSB-first transfer

    ▆ Error detection: Parity, overrun and frame error

    ▆ Auto hardware flow control mode – RTS, CTS

    ▆ IrDA SIR encoder and decoder

    ▆ RS485 mode with output enable control

    ▆ FIFO Depth: 8-level for both receiver and transmitter

    The Universal Synchronous Asynchronous Receiver Transceiver, USART, provides a flexible  full duplex data exchange using synchronous or asynchronous transfer. The USART is used to  translate data between parallel and serial interfaces, and is commonly used for RS232 standard  communication. The USART peripheral function supports four types of interrupt including Line  Status Interrupt, Transmitter FIFO Empty Interrupt, Receiver Threshold Level Reaching Interrupt  and Time Out Interrupt. The USART module includes an 8-level transmitter FIFO, (TX_FIFO) and  an 8-level receiver FIFO (RX_FIFO). The software can detect a USART error status by reading  USART Status & Interrupt Flag Register, USRSIFR. The status includes the type and the condition  of the transfer operations as well as several error conditions resulting from Parity, Overrun,  Framing and Break events.

  • Cyclic Redundancy Check – CRC

    ▆ Supports CRC16 polynomial: 0x8005, X16 + X15 + X2  + 1

    ▆ Supports CCITT CRC16 polynomial: 0x1021, X16 + X12 + X5  + 1

    ▆ Supports IEEE-802.3 CRC32 polynomial: 0x04C11DB7, X32 + X26 + X23 + X22 + X16 + X12 + X11 + X10 + X8  + X7  + X5  + X4  + X2  + X + 1

    ▆ Supports 1's complement, byte reverse & bit reverse operation on data and checksum

    ▆ Supports byte, half-word & word data size

    ▆ Programmable CRC initial seed value

    ▆ CRC computation executed in 1 AHB clock cycle for 8-bit data and 4 AHB clock cycles for 32-bit  data

    ▆ Supports PDMA to complete a CRC computation of a block of memory

    The CRC calculation unit is an error detection technique test algorithm and is used to verify data  transmission or storage data correctness. A CRC calculation takes a data stream or a block of data  as its input and generates a 16-bit or 32-bit output remainder. Ordinarily, a data stream is suffixed  by a CRC code and used as a checksum when being sent or stored. Therefore, the received or  restored data stream is calculated by the same generator polynomial as described above. If the new  CRC code result does not match the one calculated earlier, that means the data stream contains a  data error.

  • Peripheral Direct Memory Access – PDMA

    ▆ 6 channels with trigger source grouping

    ▆ 8-bit, 16-bit and 32-bit width data transfer

    ▆ Supports linear address, circular address and fixed address modes

    ▆ 4-level programmable channel priority

    ▆ Auto reload mode

    ▆ Supports trigger sources: ADC, SPI, USART, UART, I2 C, MCTM, GPTM, SCTM and software request

    The Peripheral Direct Memory Access circuitry, PDMA, moves data between the peripherals  and the system memory on the AHB bus. Each PDMA channel has a source address, destination  address, block length and transfer count. The PDMA can exclude the CPU intervention and avoid  interrupt service routine execution. It improves system performance as the software does not need  to connect each data movement operation.

  • Hardware Divider – DIV

    ▆ Signed / unsigned 32-bit divider

    ▆ Calculate in 8 clock cycles, load in 1 clock cycle

    ▆ Division by zero error Flag

    The divider is the truncated division and requires a software triggered start signal by controlling  the "START" bit in the control register. The divider calculation complete flag will be set to 1 after  8 clock cycles, however, if the divisor register data is zero during the calculation, the division by  zero error flag will be set to 1.

  • Debug Support

    ▆ Serial Wire Debug Port – SW-DP

    ▆ 4 comparators for hardware breakpoint or code / literal patch

    ▆ 2 comparators for hardware watch points

  • Package and Operation Temperature

    ▆ 48-pin LQFP-EP and 32-pin QFN packages

    ▆ Operation temperature range: -40 °C to 105 °C

Device Information


Block Diagram


Memory Map

Holtek MCU HT32F52220


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