Fast prototyping board 16-bit single-chip microcontrollers (37 pages)
Summary of Contents for Renesas RH850/E2 Series
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All information contained in these materials, including products and product specifications, represents information on the product at the time of publication and is subject to change by Renesas Electronics Corp. without notice. Please review the latest information published by Renesas Electronics Corp. through various means, including the Renesas Technology Corp.
Table of Contents Chapter 1 Introduction ................. 3 Chapter 2 Overview ................4 Overview of Y-RH850-E2X-292PIN-PB-T1-V1 ........4 Mounting of the device ................ 5 Chapter 3 Power supply ............... 6 Board power connection ..............6 Voltage distribution ................7 Chapter 4 Clock sources ..............
The RH850/E2x Application Board is part of the RH850 Evaluation Platform and serves as a simple and easy to use platform for evaluating the features and performance of Renesas Electronics 32-bit RH850/E2x microcontrollers in a BGA-292 package. The PiggyBack board (Y-RH850-E2X-292PIN-PB-T1 -V1) can be used as a standalone board, or can be mated with a mainboard (Y- RH850-X1X-MB-Tx-Vx) for extended functionality.
Chapter 2 Overview Overview of Y-RH850-E2X-292PIN-PB-T1-V1 Figures 1 and 2 provide a schematic view of the Y-RH850-E2X-292PIN-PB-T1- V1 PiggyBack board. RH850-E2X-292PIN-PB-T1-V1 EESS-0401-153-02 Figure 1 PiggyBack Board Top View The red arrow denotes the position of socket pin #1. Figure 2 PiggyBack Board Bottom View R20UT4084ED0130 Rev.
Mounting of the device The Y-RH850-E2X-292PIN-PB-T1-V1 PiggyBack board features a socket for mounting of the device. All E2x in BGA-292 package do fit into the available Enplas OTB-292(961RS)-0.8-019S-00 socket. The device must be placed inside the socket IC1. To insert the device align the device package #1pin with the #1pin of the socket.
Chapter 3 Power supply Board power connection For operation of the device, a supply voltage must be connected to the board. There are several possibilities to power the device. Within this document, the following voltages are considered as ‘typical’ values: Voltage1 = 5V Voltage2 = 3.3V Voltage3 = 1.25V...
Voltage distribution The table shows the required device power supply pins. For detailed explanation of their function and specification, please refer to the user documentation of the corresponding device: Table 1 Available Power Domains for MCU Device Supply Pin SYSVCC EnVCC (n = 0-2) LVDVCC EMUVCC...
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Note: Although nominally 1.25V is used even as name in the schematic the output of the voltage regulator IC19 is slightly increased to 1.28V (see Chapter 11 ‘Schematic’). With this sufficient high voltage is applied, even in case of any possible voltage drops. +3.3V JP11 E0VCC...
Chapter 4 Clock sources External crystal oscillators for the device clock supply are provided with the board. 4.1.1 MainOsc A crystal or ceramic resonator can be mounted on socket X1. A 20MHz and a 40MHz oscillator are supplied with the board. The signals X1 and X2 are by default not connected to a pin header in order to minimize disturbance on the resonator signal.
Chapter 5 Debug and Programming interface The signal ‘EVTO’ from below connectors can be pulled up to ‘E0VCC’ via JP28. Please refer to the documentation of the used tool, whether this is needed. The signal ‘TRST’ from below connectors can be pulled up to ‘SYSVCC’ or to the ‘TRST’...
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Reserved (NC) Reserved (NC) TRST Reserved (NC) Reserved (NC) EVTI (P33_8) EVTO (P33_9) Reserved (NC) Reserved (NC) RES_IN Reserved (NC) CICREFP Reserved (NC) CICREFN Reserved (NC) DRDY Reserved (NC) RES_OUT Access to the signal AURORES is possible via jumper JP34. With this jumper, AURORES can also be connected to TRST or pulled-down to GND.
Chapter 6 Connectors for ports of device Connection to most functional pins of the devices is possible via the connectors CN5 to CN8 and CN18. Some functions might not be available on the pin headers, e.g. high frequency signals, as this would disturb the integrity of such signals. The actual voltage levels of the various voltage domains can be measured at the individual jumpers.
CAN2TX P02_0 CTX0 CAN2RX P02_2 CRX0 CAN3TX P32_6 CTX3 CAN3RX P32_4 CRX3 CAN4TX P15_7 CTX4 CAN4RX P15_8 CRX4 RHSIF I/F CN11 is available to connect to the RHSIF I/F signals of the device. The connector is a Samtec ‘ERF8-005-05.0-L-DV-L-TR’ type connector and the following table shows the signal assignment.
JP29 pins 1 and 2 connected: Function *1 is effective JP29 pins 2 and 3 connected: Function *2 is effective Note 3: The function of the pin P14_2 can be configured in the used MCU device. For details, please refer to the HW user's manual of the used device. All signals are by default not connected to a pin header in order to minimize disturbance on the signal.
Chapter 7 Other circuitry Signalling for ERROROUT_M A red LED (LED4) is available two indicate a “low” output signal from ERROROUT_M. Pin Headers for Pull-Down and Pull-Up A connector CN9 is available to enable easy connection to 3.3V / 5V or GND via pull-up or pull-down resistances, respectively.
Chapter 8 Jumper Configuration Jumper are available to configure the function of the board. This chapter describes the standard configuration, i.e. jumper setting for the intended devices, to enable basic operation. For a detailed explanation of the supported function of the used device, please refer to the corresponding HW user’s manual.
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#x-#y: Connect the pins #x and #y for the standard configuration. Possible to configure depending on the use case and on the allowed specification of the used device. A small circle near the jumper on the board and a rectangular representation of the pin in the overview picture in sec.
Chapter 9 Precautions Power-Off Sequence A dedicated sequence needs to be applied, when the power supplied to the board is turned off. Please follow below sequence: 1. At first press the reset push-button SW1 and keep the button pushed down (keep the Reset asserted) 2.
Chapter 11 Schematic CAUTION: The schematics shown in this document are not intended to be used as a reference for mass production. Any usage in an application design is in sole responsibility of the customer. The following components described in the schematic are not provided with the board: ...
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CR-1 : @RH850_E2X_292PIN_PB_T1_V1_LIB.RH850_E2X_292PIN_PB_T1_V1(SCH_1):PAGE1 Changes Date Component Version E0VCC AN00<3..0> AN00_<3..0> 2D6< 1C4< 3.3V or 5V A2VREFH E1VCC 49.9 3.3V or 5V 3.3V or 5V E2VCC 3.3V or 5V ADSVCC ADSVCL 49.9 3.3V or 5V 3.3V or 5V EMUVCC 3.3V ADSVREFH 49.9 A0VCC 3.3V or 5V...
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CR-4 : @RH850_E2X_292PIN_PB_T1_V1_LIB.RH850_E2X_292PIN_PB_T1_V1(SCH_1):PAGE4 PUSH BUTTON FOR RESET Aurora I/F DEBUG AND PROGRAMMING INTERFACE BOARD_VCC SYSVCC BOARD_VCC 3.3V or 5V 3.3V or 5V SYSVCC 3.3V or 5V 3.3V or 5V Min 5ms from VCC up to resetz up R125 E0VCC 3.3V or 5V 3.3V or 5V TLC7701ID header 3way long jumper 2.54mm...
Chapter 12 Revision History The table provides information about the major changes of the document versions. Date Version Description 2017-05-23 Initial release R20UT4084ED0130 Rev. 1.3 2020-05-12...
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"Specific" without the prior written consent of Renesas Electronics. Further, you may not use any Renesas Electronics product for any application for which it is not intended without the prior written consent of Renesas Electronics. Renesas Electronics shall not be in any way liable for any damages or losses incurred by you or third parties arising from the use of any Renesas Electronics product for an application categorized as "Specific"...
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