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MAXIM New Products - DS28EL25 & MAX8967
2013-03-05
DS28EL25
DeepCover Secure Authenticator with 1-Wire SHA-256 and 4Kb User EEPROM
Protect Your Development Investment with Crypto-Strong Authentication and Advanced Physical Security
Description
DeepCover™ embedded security solutions cloak sensitive data under multiple layers of advanced physical security to provide the industry’s most secure key storage possible. The Deepcover Secure Authenticator (DS28EL25) combines crypto-strong, bidirectional, secure challenge-and-response authentication functionality with an implementation based on the FIPS 180-3-specified Secure Hash Algorithm (SHA-256). A 4Kb user-programmable EEPROM array provides nonvolatile storage of application data and additional protected memory holds a read-protected secret for SHA-256 operations and settings for user memory control. Each device has its own guaranteed unique 64-bit ROM identification number (ROM ID) that is factory programmed into the chip. This unique ROM ID is used as a fundamental input parameter for cryptographic operations and also serves as an electronic serial number within the application. A bidirectional security model enables two-way authentication between a host system and slave-embedded DS28EL25. Slave-to-host authentication is used by a host system to securely validate that an attached or embedded DS28EL25 is authentic. Host-to-slave authentication is used to protect DS28EL25 user memory from being modified by a nonauthentic host. The SHA-256 message authentication code (MAC), which the DS28EL25 generates, is computed from data in the user memory, an on-chip secret, a host random challenge, and the 64-bit ROM ID. The DS28EL25 communicates over the single-contact 1-Wire® bus at overdrive speed. The communication follows the 1-Wire protocol with the ROM ID acting as node address in the case of a multiple-device 1-Wire network.
Key Features
- Symmetric Key-Based Bidirectional Secure Authentication Model Based on SHA-256
- Dedicated Hardware-Accelerated SHA Engine for Generating SHA-256 MACs
- Strong Authentication with a High Bit Count, User-Programmable Secret, and Input Challenge
- 4096 Bits of User EEPROM Partitioned Into 16 Pages of 256 Bits
- User-Programmable and Irreversible EEPROM Protection Modes Including Authentication, Write and Read Protect, and OTP/EPROM Emulation
- Unique, Factory-Programmed 64-Bit Identification Number
- Single-Contact 1-Wire Interface Communicates with Host at Up to 76.9kbps
- Operating Range: 1.8V ±5%, -40°C to +85°C
- Low-Power 5µA (typ) Standby
- ±8kV Human Body Model ESD Protection (typ)
- 6-Pin TDFN Package
MAX8967
Dual Step-Down Converters with 6 LDOs for Baseband and Applications Processor
Achieve Smaller Component Size and Board Area with This Integrated Solution
Description
The MAX8967 is an µPMIC with two DC-to-DC step-down switching converters and six remote capacitor-capable LDOs. The step-down converters deliver up to 2A of output current independently. Two of the LDOs deliver a load current up to 300mA, while the remaining four deliver up to 150mA. Both step-down converters have remote sense, allowing loads to be placed away from the IC. The IC operates over a 2.6V to 5.5V input supply range.
Fixed-frequency 4.4MHz PWM operation and clocks that are 180° out of phase permit the use of small external components. Under light load conditions, the step-down converters automatically switch to skip mode operation. In skip mode operation, switching occurs only as needed, allowing efficient operation. Placing either of the step-down converters into green mode reduces the quiescent current consumption of that converter to 5µA (typ).
The IC supports dynamic adjustment of the output voltage through its I²C interface. Each step-down converter has two register settings for output voltage and a setting for ramp rate. Also, each step-down converter has a dedicated enable pin and a dedicated VID pin to toggle between the two programmed output voltages. Additionally, an interrupt output is provided, allowing the IC to signal its master.
Fixed-frequency 4.4MHz PWM operation and clocks that are 180° out of phase permit the use of small external components. Under light load conditions, the step-down converters automatically switch to skip mode operation. In skip mode operation, switching occurs only as needed, allowing efficient operation. Placing either of the step-down converters into green mode reduces the quiescent current consumption of that converter to 5µA (typ).
The IC supports dynamic adjustment of the output voltage through its I²C interface. Each step-down converter has two register settings for output voltage and a setting for ramp rate. Also, each step-down converter has a dedicated enable pin and a dedicated VID pin to toggle between the two programmed output voltages. Additionally, an interrupt output is provided, allowing the IC to signal its master.
Key Features
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Multi-Output PMIC in a Compact Package
- Two 2A Step-Down Converters with Remote Output Voltage Sensing
- Two 300mA LDOs
- Four 150mA LDOs
- < 1µA Shutdown Current
- 2.32mm x 2.44mm Package
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Versatile Step-Down Converters
- Programmable Output Voltage (0.6V to 3.3875V) Through I²C Bus
- Programmable Output Voltage Slew Rate (12.5mV/µs to 50mV/µs)
- Dynamic Switching Between Two Output Voltages Through VID_ Pins
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Efficient Step-Down Converters
- Over 95% Efficiency with Internal Synchronous Rectifier
- Automatic Skip Mode at Light Loads
- Low 61µA (typ) Quiescent Current
- 5µA (typ) Green Mode per Step-Down Converter
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Programmable LDOs
- Programmable Output Voltage (0.8V to 3.95V in 50mV Steps)
- Programmable Soft-Start Slew Rate (5mV/µs–100mV/µs)
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Reduces Component Size and Board Area Solution
- 4.4MHz Step-Down Switching Allows for 1µH Inductors
- COUT = 1µF for All LDOs
- Reduced Board Space with Remote Capacitor LDOs
- Internal Feedback for Step-Down Converters and LDOs