Jumpers

3.1.1JMP1: Short R1

In order to allow current output IDAC0 to have full compliance, JMP1 can be used to short out resistor R1, which is in series with that signal.

3.1.2JMP2: Short R2

In order to allow current output IDAC0 to have full compliance, JMP2 can be used to short out resistor R2, which is in series with that signal.

3.1.3JMP3: I2C Data SDA Enable

The MSC1211 uses the same signals for SPI and I2C. Since there is no chip select available for the I2C device, this jumper will allow the isolation of the 256K EEPROM during SPI testing.

3.1.4JMP3: I2C Data SCL Enable

The MSC1211 uses the same signals for SPI and I2C. Since there is no chip select available for the I2C device, this jumper will allow the isolation of the 256K EEPROM during SPI testing.

3.1.5JMP5: AVDD Power Source Select

The MSC1211 has separate analog and digital power supplies. Use JMP5 to connect the desired voltage source for the analog power supply AVDD. Short- ing pins 1 and 2 connects the onboard 5V regulator. Pins 2–3 can be used to

supply an external voltage for use as AVDD; pin 2 is for the external voltage and pin 3 is for AGND.

3.1.6JMP6: DVDD Power Source Select

The MSC1211 has separate analog and digital power supplies. Use JMP6 to connect the desired voltage source for the digital power supply DVDD. Shorting pins 1 and 2 connects the onboard 5V regulator. Pins 2–3 can be used to sup-

ply an external voltage for use as DVDD; pin 2 is for the external voltage and pin 3 is for AGND.

3.1.7J7: Reference Select

J7 has six pins. For normal operation pins 1 and 2 are connected for REF IN– to be connected to AGND. Since the MSC1210 has a very similar pinout to the MSC1210, the MSC1211 board is designed to accommodate the MSC1210 device. For the MSC1210, the VDAC1 pin is the REFOUT pin. Therefore, a connection between pins 3 and 4 will provide the other required connection for use of the internal reference for the MSC1210. Only pins 1 and 2 are needed for the MSC1211. Pins 4 and 6 can be connected together, if you want to use AVDD as the reference voltage.

3.1.8J16: Memory Configuration

The MSC1211EVM can use either RAM or EEPROM in the socket for U9. The J16 jumper provides the capability to configure the Addressing and Write En- able signals for each use. For use with compatible EEPROMs, the following pins are shorted: 1–2, 3–5 and 4–6. For use with the RAM memory that comes stan- dard on the MSC1211EVM, the following pins are shorted: 1–3, 2–4, 5–6.

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Texas Instruments MSC1211 manual 1 JMP1 Short R1, 2 JMP2 Short R2, 3 JMP3 I2C Data SDA Enable, 4 JMP3 I2C Data SCL Enable

MSC1211 specifications

Texas Instruments MSC1211 is a highly integrated, low-power microcontroller designed specifically for applications requiring high accuracy and precision in signal processing. As a member of the Texas Instruments Microcontroller family, the MSC1211 targets industrial automation, medical instrumentation, and portable measurement devices, making it a versatile choice for designers across various industries.

One of the standout features of the MSC1211 is its 16-bit ADC (Analog-to-Digital Converter) that boasts a resolution of 16 bits, which enables the microcontroller to accurately convert analog signals into digital data. This high resolution makes it suitable for applications where precision is paramount, such as in medical devices that require accurate readings from sensors. The device can achieve sampling rates up to 1 kSPS (kilo Samples Per Second), making it efficient for real-time signal processing.

Another key characteristic of the MSC1211 is its low power consumption. The microcontroller employs advanced power management features, allowing it to operate in various power modes, making it ideal for battery-operated devices. The sleep mode dramatically reduces power consumption, extending the operational life of portable equipment significantly.

The MSC1211 features a built-in digital signal processor (DSP) that facilitates efficient data processing and filtering, enabling complex algorithms to be executed on the captured signals in real-time. This capability simplifies design considerations for developers, reducing the need for external DSP chips and enhancing system integration.

Connectivity is another significant aspect of the MSC1211. It supports standard communication protocols such as SPI (Serial Peripheral Interface) and I2C (Inter-Integrated Circuit), making it easy to interface with a variety of sensors and peripherals. This flexibility is crucial in today's interconnected world, allowing developers to design scalable systems that can accommodate future upgrades and enhancements.

Moreover, the microcontroller incorporates onboard memory, including RAM and Flash memory, ensuring ample storage for application codes and operational data. The flexibility in memory allocation allows developers to optimize their applications, balancing memory usage with processing speed.

In summary, the Texas Instruments MSC1211 microcontroller stands out for its high-resolution ADC, low power consumption, integrated DSP capabilities, and flexible communication options. These features make it an exceptional choice for applications in diverse fields such as medical devices, industrial automation, and portable measurement systems, ensuring precision and efficiency in performance.